Abstract
Primary sensory circuits encode both weak and intense stimuli reliably, requiring that their synapses signal over a wide dynamic range. In the retinal circuitry subserving night vision, processes intrinsic to the rod bipolar (RB) cell presynaptic active zone (AZ) permit the RB synapse to encode signals generated by the absorption of single photons as well as by more intense stimuli. In a study using an in vitro slice preparation of the mouse retina, we provide evidence that the location of Ca channels with low open probability within nanometers of the release sites is a critical determinant of the physiological behavior of the RB synapse. This gives rise to apparent one-to-one coupling between Ca channel opening and vesicle release, allowing presynaptic potential to be encoded linearly over a wide dynamic range. Further, it permits a transition from univesicular to multivesicular release (MVR) when two Ca channels/AZ open at potentials above the threshold for exocytosis. MVR permits small presynaptic voltage changes to elicit postsynaptic responses larger than quantal synaptic noise.
Introduction
During scotopic (night) vision, the responses of individual rods are propagated to ganglion cells (GCs) by the well-characterized rod bipolar (RB) pathway, as follows: rod → RB → AII amacrine cell → cone bipolar cell → GC (Bloomfield and Dacheux, 2001; Field et al., 2005). Convergence of rod outputs makes individual GCs quite sensitive but presents the RB pathway with two signal-processing problems: (1) separating sparse rod signals from noise at visual threshold; and (2) preventing saturation of the circuitry as light intensity increases by orders of magnitude (Field et al., 2005). Noise reduction is implemented at the rod–RB synapse, and gain is controlled at the RB–AII synapse; amplification follows noise reduction, as is computationally appropriate (Field and Rieke, 2002; Dunn et al., 2006; Dunn and Rieke, 2008). The location of gain control indicates that the intrinsic properties of RB synapses underlie their ability to convey scotopic visual signals over a wide dynamic range.
The coupling between presynaptic Ca influx and the exocytotic machinery exerts a profound influence on the operating range of a synapse. RBs possess ribbon-type active zones (AZs); a near-linear relationship between Ca2+ influx and exocytosis has been observed at many ribbon synapses and likely underlies their dynamic range (Thoreson et al., 2004; Brandt et al., 2005; Johnson et al., 2005, 2010; Sterling and Matthews, 2005; Keen and Hudspeth, 2006; Goutman and Glowatzki, 2007). Two cellular mechanisms have been proposed to account for this near linearity: (1) unique Ca2+ sensors (otoferlin or non-neuronal synaptotagmins) may initiate exocytosis at ribbon synapses (Thoreson et al., 2004; Dulon et al., 2009; Johnson et al., 2010); and (2) release sites may be controlled by the opening of single Ca channels (the nanodomain control hypothesis) (Brandt et al., 2005; Goutman and Glowatzki, 2007; Li et al., 2009).
Here, we assayed synaptic transmission from RBs to AIIs in a mouse retinal slice preparation to distinguish between these possibilities and to investigate the mechanism(s) responsible for the dynamics of transmission at the RB–AII synapse. First, we determined that exocytosis from RBs is controlled by a conventional vesicular sensor activated by cooperative binding of multiple Ca2+ and that release sites are activated by [Ca2+] nanodomains. Second, we found that nanodomain control of exocytosis permitted a transition from univesicular to multivesicular release (MVR) at potentials encountered during RB responses to single photon absorptions. Specifically, physiological stimuli evoked MVR only when presynaptic depolarizations opened multiple Ca channels/AZ; exocytosis evoked by the opening of one channel/AZ was univesicular. Thus, nanodomain control of exocytosis underlies two important properties of the RB pathway: high gain and a wide dynamic range.
Materials and Methods
Tissue preparation.
Experiments were performed on slices (200 μm) prepared from light-adapted retinae isolated from wild-type or Grm6-GFP C57bl/6 mice of either sex (4–8 weeks old). The Grm6-GFP mouse expresses green fluorescent protein (GFP) in all ON bipolar cells, including RBs (Morgan et al., 2006), and was used to target RB terminals for recording. The Animal Care and Use Committee of Northwestern University approved all procedures involving animal use.
Retinae were isolated into bicarbonate buffered Ames medium (Sigma) equilibrated with 95% O2/5% CO2 (carbogen) at room temperature. For retinal slice preparation, retinae then were embedded in low-melting-temperature agarose (Sigma; type VIIA, 3% in a HEPES-buffered saline), and slices were cut on a vibrating microtome (Microm Corporation). Slices were stored in carbogen-bubbled Ames medium at room temperature until use.
Data collection.
All experiments were performed at near-physiological temperature (∼34°C). Retinal slices were superfused with a carbogen-bubbled artificial CSF (ACSF) containing the following (in mm): 119 NaCl, 23 NaHCO3, 10 glucose, 1.25 NaH2PO4, 2.5 KCl, 2 NaLactate, and 2 NaPyruvate. CaCl2 and MgCl2 were added at varying concentrations to maintain the total divalent cation concentration at 4 mm (e.g., 1 mm CaCl2 and 3 mm MgCl2). Picrotoxin (100 μm); 1,2,5,6-tetrahydropyridin-4-yl) methylphosphinic acid (50 μm); strychnine (0.5 μm); tetrodotoxin (TTX, 500 nm); 2-amino-4-phosphonobutyrate (l-AP4, 2 μm); and niflumic acid (100 μm) were added to the ACSF to block GABAA receptor-, GABAC receptor-, glycine receptor-, voltage-gated Na-, mGluR6-regulated, and Ca2+-activated Cl channel-mediated currents, respectively. Drugs were obtained from Sigma or Tocris Bioscience (except for TTX, from Alamone Labs).
Pipettes were filled with the following (in mm): 90 Cs-methanesulfonate, 20 tetraethylammonium-Cl, 1 4-AP, 10 HEPES, 1 BAPTA, 8 Tris-phosphocreatine, 4 Mg-ATP, and 0.4 Na-GTP. Voltage-clamp recordings were made from both RBs and AIIs. Generally, RB holding potential was −60 mV and AII holding potential was −90 mV, and membrane potentials are corrected for junction potentials of approximately −10 mV. Access resistances were <40 ΜΩ for RBs and <20 ΜΩ for AII amacrines, and were compensated by 50–90%. Recordings were made using a single MultiClamp 700B amplifier. Synaptic transmission was elicited by stimulation of individual RBs at 10–20 s intervals. Recorded currents and potentials were low pass filtered at 2–8 kHz and digitized at 10–50 kHz by an ITC-18 A/D board (Instrutech) controlled by software written in IGOR Pro (WaveMetrics).
Data analysis.
Analysis was performed in Igor Pro and Excel (Microsoft). Recorded Ca currents were leak subtracted offline (P/4 protocol). Paired, two-tailed t tests were used to compare paired datasets; ANOVA was used to compare unpaired datasets, and the Mann–Whitney U test was used to compare amplitude and rise time distributions. In all cases, significance was accepted as p < 0.05. Nonstationary variance analysis was used to estimate single Ca channel conductance. Unless indicated otherwise, data are presented as mean ± SEM, and illustrated traces are averages of 5–10 responses. The traces illustrated in Figure 4A and supplemental Figure 3F (available at www.jneurosci.org as supplemental material) were digitally filtered at 1 kHz for the purpose of display only.
Results
The exocytotic machinery uses a conventional Ca2+ sensor that is saturated by physiological [Ca2+]e
At conventional synapses, a steep relationship between [Ca2+]e and exocytosis is well described and is presumed to reflect the requirement for the binding of multiple Ca2+ to the vesicular sensor to initiate release (Dodge and Rahamimoff, 1967). We wished to determine whether the vesicular Ca2+ sensor at the RB synapse exhibited a similarly steep dependence on [Ca2+]e. To do this, we assayed AMPA receptor (AMPAR)-mediated EPSCs evoked by tail Ca currents as the [Ca2+]e was varied between 0.2 and 2 mm (Fig. 1A) (we believe this to be the first time this classic experiment has been performed using a retinal synapse). To prevent rundown of synaptic transmission from affecting our measurements, only two [Ca2+]e were used for each experiment: 0.2 mm and 0.4, 0.6, 1, or 2 mm. We analyzed only recordings in which at least 10 stable responses were observed in each solution. Transmission in 0.2 mm [Ca2+]e exhibited a large and very consistent number of failures (42 ± 8%, n = 20 paired recordings), and EPSC and Ca current parameters for each recording were normalized to those measured in 0.2 mm [Ca2+]e.
The maximal tail current-evoked EPSC reflects the release of only ∼60% of the readily releasable pool (RRP) of vesicles (n = 9, data not shown) (also see Singer and Diamond, 2006), and using a brief stimulus that does not deplete the RRP removes consideration of vesicle cycling from the interpretation of our experiments. Additionally, Ca tail currents are not contaminated by the H+-dependent inhibition of the presynaptic Ca channels that arises at some retinal ribbon synapses after MVR of acidic glutamatergic vesicles (supplemental Fig. 1A,B, available at www.jneurosci.org as supplemental material) (DeVries, 2001; Palmer et al., 2003). Further, we find that the recorded presynaptic currents reflect accurately the underlying Ca conductance changes mediating exocytosis; i.e., our voltage-clamp is adequate (supplemental Fig. 1C,D, available at www.jneurosci.org as supplemental material).
We plotted both the quantal content of and the peak release rate [estimated by de-convolving the average quantal miniature EPSC (mEPSC) from the EPSC] (Singer et al., 2004) reflected by EPSCs against the normalized Ca current integral (QCa) (Fig. 1B,C) and found that the relationship between Ca2+ influx and exocytosis was well described by a Hill function with a coefficient ≈5. Our observation is consistent with previous studies of other ribbon synapses: exocytosis evoked by photolysis of “caged” Ca2+ appears to require the binding of multiple (4–5) Ca2+ to a vesicular sensor (Heidelberger et al., 1994; Beutner et al., 2001). RBs express synaptotagmin 1 (Fox and Sanes, 2007), and we presume that this molecule acts as a Ca2+ sensor for exocytosis at this ribbon synapse as it does at many conventional synapses.
Additionally, we found that the exocytotic process appeared near saturation at 1 mm [Ca2+]e, close to the physiological [Ca2+]e in the retina (Ames and Nesbett, 1981). Supporting this notion, the paired-pulse ratio (PPR) of the amplitudes of two EPSCs evoked 100 ms apart tracked the EPSC–[Ca2+]e relationship closely and did not decline at [Ca2+]e >1 mm, indicating that release probability did not increase at elevated [Ca2+]e (PPR = 0.39 ± 0.1 at 1 mm and 0.45 ± 0.1 at 2 mm Ca2+; p = 0.46; n = 9 paired recordings). Though it is thought that postsynaptic AMPARs at the RB–AII synapse are not saturated by MVR (Singer et al., 2004; Singer and Diamond, 2006; Singer, 2007), we thought it necessary to confirm that postsynaptic receptor saturation did not distort our measurements of the EPSCs at higher [Ca2+]e. We did this in two ways, and the resulting data are presented in supplemental Figure 2 (available at www.jneurosci.org as supplemental material). These observations confirm that the plateau of the relationship between the EPSC and [Ca2+]e reflects saturation of the release machinery at physiological [Ca2+]e. In this respect, the RB synapse differs significantly from hair cell ribbon synapses as well as conventional synapses (Schneggenburger et al., 1999; Brandt et al., 2005).
A linear relationship between the number of open channels and the EPSC
As exocytosis from the presynaptic RB AZ appears to be steeply dependent on Ca2+ flux through presynaptic Ca channels, next we explored the possibility that [Ca2+] nanodomains generated by the opening of single channels control individual release sites. To do this, we altered presynaptic Ca2+ influx by changing the number of open Ca channels and examined concomitant changes in the EPSC (Brandt et al., 2005; Gentile and Stanley, 2005; Shahrezaei et al., 2006; Bucurenciu et al., 2010). Three experiments were performed. In experiment 1, in a saturating (2.5 mm) [Ca2+]e, we applied a low concentration (3 μm) of the Ca channel antagonist isradipine, sufficient to block the Ca current by ∼50%. As isradipine antagonizes Ca channels by inducing entry into an inactivated (i.e., nonconducting) state, this manipulation effectively prevents some portion of the channels from contributing any Ca2+ to the release process (Berjukow et al., 2000; Hering et al., 2005). Thus, if Ca2+ flux through individual channels controls exocytosis from individual release sites, this manipulation should reduce the EPSC by ∼50% despite the fact that the remaining Ca current is equivalent in amplitude to the Ca current recorded in 1.25 mm [Ca2+]e, a near-saturating [Ca2+]e. Indeed, isradipine blocked the EPSC by 45 ± 9% as it reduced the Ca current by 41 ± 7%, suggesting a 1:1 relationship between the number of open Ca channels and the number of release sites activated (n = 3) (Fig. 2A).
In experiment 2, we changed the number of open channels by delivering brief (1–2 ms) presynaptic voltage steps of varying amplitude. These step activated varying numbers of channels, and exocytosis was evoked primarily during the Ca current tail, when the driving force on Ca2+ was constant (Fig. 2B). The amplitude of evoked EPSCs varied with the magnitude of the presynaptic depolarization. From recording to recording, we observed a consistent number of failures of transmission after the smallest voltage step (44 ± 5% of responses; n = 10 recorded pairs). Therefore, we normalized the Ca current and EPSC measurements for each recording to the values of the responses to the smallest step. The relationship between EPSC quantal content and QCa (integrated over the entire step, not just the current tail) is plotted in Figure 2B: it is nearly linear and described by a Hill function with a coefficient of 1.1.
In experiment 3, we changed the number of open channels by eliciting Ca tail currents with voltage steps of varying length (0.1–0.3 ms) (Fig. 2C) (Llinás et al., 1981; Gentile and Stanley, 2005). Lengthening the duration of depolarization increased the number of presynaptic Ca channels activated and therefore raised the amplitude of the EPSC (Fig. 2C1). In performing these experiments, we were able to elicit Ca currents and EPSCs of a range of amplitudes within a single recorded pair. Consequently, we could plot the relationship between EPSC quantal content and presynaptic QCa for each recorded pair (e.g., Fig. 2C2). These relationships were described by Hill functions with coefficients near 1 (for n = 3 recorded pairs, the Hill coefficients were 1.3, 1.6, and 1.4). In performing these experiments, we found it difficult to adjust the duration of the briefest voltage steps to yield a consistent number of failures of transmission (as described above). Therefore, to summarize the results of these experiments, we normalized the Ca current and EPSC measurements to the responses elicited by the longest voltage step and binned the data in increments of 0.15 to average between recorded pairs (Fig. 2C3). The relationship between average EPSC quantal content and average QCa was approximately linear and described by a Hill function with a coefficient of 1.4 (n = 3).
It seems, then, that the opening of single Ca channels controls the release of individual vesicles (Yoshikami et al., 1989; Quastel et al., 1992; Bertram et al., 1999). The spatial relationship between Ca channels and release sites was investigated further with an additional series of experiments supplemented by simple simulations (supplemental Fig. 3, available at www.jneurosci.org as supplemental material). This supplementary line of inquiry provides additional support for our conclusion that the dynamics of transmission at the RB–AII synapse derive from the close coupling between Ca channels and release sites. Next, though, we wished first to determine the number of Ca channels open at the presynaptic terminal and second to determine whether we could observe directly exocytosis evoked by the opening of a single Ca channel using a physiologically relevant presynaptic stimulus.
Ca channel conductance
To determine the number of presynaptic Ca channels activated by our voltage stimuli, we estimated the charge flux through a single Ca channel by nonstationary variance (NSV) analysis of macroscopic Ca currents recorded in the whole-cell configuration from RB terminals (Sigworth, 1980). This task was facilitated by the use of transgenic mice in which ON bipolar cells, including RBs, express GFP, making it possible to visualize RB terminals and target them for recording (Morgan et al., 2006).
A train of five to six voltage steps (2–10 ms with a 55 ms interpulse interval, repeated at least 20 times) from −60 to −30 mV was used to depolarize RBs and elicit Ca currents. [Ca2+]e was 2.5 mm to increase Ca current amplitude. We calculated the current variance as the averaged square of the difference between each individual response (not leak subtracted) (Roberts et al., 1990). The averaged leak-subtracted (P/4; 4 trains of 5–6 steps to −67.5 mV were applied; the step duration and interpulse interval were 2–10 and 55 ms, respectively) current–variance relationship was binned (20 bins) and plotted (Fig. 3B). The relationship was observed to be nonparabolic, indicating a low maximal open probability (Popen,max) for the Ca channels. Therefore, the single-channel current was taken as the slope of a line fit to the data. Fitting was performed only on data points acquired >1 ms after the voltage step to avoid contamination by any variance associated with transient capacitative currents. It is important to note that changes in variance were not associated with the purely passive currents evoked for leak subtraction, which decayed rapidly and with a monoexponential time course (τ < 0.2 ms) (Fig. 3C).
Further, in these experiments, data were filtered at 8 kHz and acquired at 50 kHz. Because the average Ca channel open time is fairly short (∼1 ms) (Fox et al., 1987), we took care to set the filter at more than five times the inverse of the channel open time to avoid attenuating the estimated current amplitude arising from brief channel openings (Silberberg and Magleby, 1993). We note that current–variance relationships were unaffected by changing the frequency at which the recordings were filtered (between 4 and 8 kHz; data not shown). Additionally, by recording from the axon terminals directly, we reduced the possibility that electrotonic filtering of single-channel currents would attenuate their estimated amplitudes.
The average single-channel current was −0.4 ± 0.1 pA (n = 6; mean ± SD). Taking ECa as +90 mV, approximately equivalent to the thermodynamic ECa, the single-channel conductance is ∼3 pS. This measurement is consistent with that reported for a study of presynaptic L-type single-channel currents in the chick ciliary ganglion (Church and Stanley, 1996). Thus, to estimate the single-channel current at multiple [Ca2+]e, we made use of the formulation presented by Church and Stanley (1996): conductance in pS = 9.2/(1 + 5.6/[Ca2+]e). Given that the average tail Ca current amplitude in 2.5 [Ca2+]e is −52 ± 7 pA (n = 14 somatic recordings) and a single RB terminal contains ∼40 separate AZs (Tsukamoto et al., 2001; Singer et al., 2004), we calculate that only approximately three to four channels open per AZ at the peak of a tail Ca current. More physiological stimuli, which may not reach levels of depolarization sufficient to achieve maximal channel open probability, then are likely to activate fewer than three channels/AZ.
To confirm the validity of our measurements, we performed two control experiments. In one, we repeated our measurements of single-channel current amplitude in the presence of the dihydropyridine agonist BayK8644 (BayK; 10 μm) (Fig. 3D,E). BayK increases channel open probability and mean open time without affecting single-channel conductance (Brown et al., 1984; Hess et al., 1984) (but, see Tavalin et al., 2004). Accordingly, Ca currents recorded in the presence of BayK were larger than those recorded in control conditions though the current–variance relationship remained nonparabolic (p = 0.03 by ANOVA; 70 ± 5 vs 53 ± 3 pA, BayK vs control; n = 9 and 6, respectively), but the average single-channel current measured in the presence of BayK was statistically indistinguishable from that measured in control conditions (0.4 ± 0.1 pA; mean ± SD; p = 0.23 by ANOVA).
In the second control experiment, we repeated our measurements in the presence of a non-dihydropyridine agonist of L-type currents, FPL 64176 (FPL; 5 μm) (Fig. 3F,G). FPL both increases the single-channel conductance and slows channel activation and deactivation (Handrock et al., 1998; Fan et al., 2001) (but, see Liu et al., 2003; Tavalin et al., 2004), and we expected that this manipulation would increase the measured single-channel current. Ca currents recorded in the presence of FPL, and 2.5 mm Ca2+ currents were larger and slower than control currents. The current–variance relationship remained nonparabolic in FPL, and the single-channel current estimated from a line fit to the data points was −0.7 ± 0.2 pA (mean ± SD; n = 7) (Fig. 3E).
The reported effects of BayK and FPL on single-channel conductance vary with the charge carrier (Ca2+ or Ba2+) and with experimental system, leading to the reasonable suggestion that these agents exert differential effects on different Ca channel α subunits (Tavalin et al., 2004). The subunit composition of the presynaptic Ca channel in the RB terminal is not certain; antibody-labeling studies have identified both Cav1.2 and Cav1.4 as candidates for the α subunit (Berntson et al., 2003; Rieke et al., 2008). Single Ca channel conductance in cardiomyocytes, which express Cav1.2, is unaffected or minimally affected by BayK and enhanced substantially by FPL (Hess et al., 1984; Lacerda and Brown, 1989; Handrock et al., 1998; Fan et al., 2001); BayK has a very small effect on single-channel conductance of recombinant Cav1.4-containing channels (Doering et al., 2005); the effects of FPL on Cav1.4-containing channels are unexplored. Comparison of the results presented here (Fig. 3) with future studies of agonist effects on recombinant receptors, then, may provide some insight into the molecular composition of the Ca channels in RB terminals.
Desynchronizing exocytosis allows the presynaptic voltage threshold for exocytosis to be determined reliably
To determine the minimum number of presynaptic Ca channels that must be activated to elicit exocytosis, we applied a slow voltage ramp (−60 to −45 mV at 0.6 mV/ms) to the soma of the presynaptic RB and recorded EPSCs in the postsynaptic AII. Evoked release was desynchronized, as has been described previously (Singer et al., 2004; Snellman et al., 2009), and we were able to examine the timing and amplitude of individual EPSCs (Fig. 4). We formulated two hypotheses: (1) that if the opening of a single channel could evoke exocytosis, we would observe EPSCs first at a threshold presynaptic voltage at which <1 Ca channel/AZ on average was open; and (2) that if the opening of a single channel could evoke exocytosis, the probability of observing EPSCs at this threshold would increase with [Ca2+]e though the threshold itself would remain constant (i.e., the number of open channels remains constant with varying [Ca2+]e, but the probability that a channel opening will evoke an EPSC increases with Ca2+ flux through individual channels).
To address these hypotheses experimentally, we examined EPSCs evoked by ramps performed when [Ca2+]e was increased from 0.4 to 0.8 mm (Fig. 4A); this concentration range encompasses the very steep portion of the [Ca2+]e/EPSC relationship (Fig. 1). We measured the amplitudes of the individual EPSCs evoked by each trial as well as the presynaptic voltage at which each EPSC occurred. EPSC amplitudes were normalized to the average mEPSC amplitude recorded in each cell and plots of amplitude versus presynaptic voltage are illustrated in Figure 4B. EPSCs became evident first at approximately −56 mV, at which point the presynaptic Ca current had an amplitude of ∼1 pA, corresponding to the opening of three to four channels distributed among the 40 RB AZs (i.e., there are ∼0.1 open channels/AZ, assuming a single-channel current of 0.12 pA at 0.8 mm [Ca2+] and 0.06 pA at 0.4 mm [Ca2+]). Assuming that channel opening is a stochastic process described by Poisson statistics, the probability of two Ca channels being open simultaneously at the same presynaptic AZ when 0.1 channels/AZ open on average is <0.005. Because a single RB contacts a single AII ∼10 times (Tsukamoto et al., 2001; Singer et al., 2004), it is likely that at this membrane potential, there is a single open Ca channel at only one of the AZs presynaptic to the recorded AII.
For each trial, we determined the presynaptic voltage at which the first EPSC was observed, and we plotted histograms of EPSCs versus presynaptic voltage in 2 mV bins (Fig. 4C). It is apparent that at both [Ca2+]e values a significant fraction of EPSCs is evoked first when the presynaptic voltage is between −57 and −50 mV, and the percentage of first events observed in this range increases with Ca2+ flux through individual channels as [Ca2+]e is raised. Specifically, EPSCs were observed in 25/170 trials (15%) conducted in 0.4 mm [Ca2+]e and in 77/170 trials (45%) when [Ca2+]e was raised to 0.8 mm. Because in these experiments the RB voltage is maintained between −60 and −50 mV for ∼17 ms (the ramp rate is 0.6 mV/ms), far longer than the mean open time of a neuronal L-type Ca channel (Nowycky et al., 1985; Fox et al., 1987), it is impossible to determine the probability with which the opening of a single Ca channel evokes exocytosis. Our observations, however, suggest that Ca2+ influx through a single Ca channel can evoke exocytosis reliably.
Additionally, it is notable that the EPSCs evoked at threshold have amplitudes similar to those of mEPSCs and therefore are likely uniquantal. Multiquantal events are observed only after the presynaptic voltage has become more depolarized and the presynaptic Ca current has become larger (corresponding to the opening of ∼1 channel/AZ). The average EPSC amplitude (binned over 3 mV increments) and the average Ca current are plotted against presynaptic voltage in Figure 4D. We were intrigued by the observation that multiquantal events were not evident when a single-channel opening triggered exocytosis and wished to determine whether single-channel openings would evoke MVR by elevating [Ca2+] concomitantly at multiple release sites were Ca2+ flux through the channels increased or intraterminal Ca2+ buffer capacity decreased. Therefore, we repeated the ramp experiment described above under two experimental conditions: (1) in the presence of a saturating [Ca2+]e of 2.5 mm; and (2) with 0.1 mm BAPTA in the pipette solution to reduce the Ca2+ buffering capacity of the presynaptic terminal.
With 2.5 mm [Ca2+]e, release events evoked at presynaptic potentials <−50 mV (corresponding to the opening of ∼0.1 channels/AZ) were observed in all trials (160 events in 134 trials). Again, because there may be multiple Ca channel openings throughout the duration of the presynaptic stimulus, we cannot determine the number of openings that precede each release event. The median presynaptic voltage at which the first EPSC was evoked, however, was more hyperpolarized than in 0.4 or 0.8 mm (Fig. 4B,C), consistent with the notion that increasing Ca2+ influx through individual channels increases the probability that a vesicle at a nearby release site will undergo exocytosis. The amplitudes of EPSCs evoked at potentials hyperpolarized to −50 mV, however, remained equivalent to those of quantal mEPSCs (Fig. 4B,D). Similarly, reducing the exogenous buffer concentration in the presynaptic terminal 10-fold, to 0.1 mm BAPTA ([Ca2+]e = 1 mm), did not affect amplitudes of release events evoked by depolarization to potentials <−50 mV (Fig. 4B,D) (events were seen in 18/47, or 38%, of trials). These observations support the notion that the opening of a single Ca channel at a single AZ is sufficient to elicit exocytosis of a single vesicle but is insufficient to elevate [Ca2+] at multiple release sites and thereby support MVR.
MVR appears to require the opening of multiple channels/AZ
We observed in all [Ca2+]e that multiquantal events occurred only when the presynaptic voltage was depolarized to −50 mV (Fig. 4B,D). At this potential, one Ca channel on average opens at each AZ. When an ensemble current arises from the contribution of, on average, one stochastic channel opening/AZ, Poisson statistics predict that 26% of AZs will contribute more than one open channel (and 35% of AZs will have no open channels). As exocytosis at the RB synapse is a binomial process (Singer et al., 2004), we postulated that slightly more than one-quarter of the evoked EPSCs that we recorded would be multiquantal if the opening of multiple Ca channels was required to evoke MVR.
Indeed, we found this to be the case. To estimate the number of multiquantal events, we calculated the area of the evoked EPSC distribution that did not overlap with the mEPSC distribution (both distributions contained normalized data pooled from multiple recordings and were significantly different as determined by the Mann–Whitney U test). The percentage of multiquantal events was similar in different [Ca2+]e and was close to the percentage of AZs predicted to have at least two open Ca channels: 30% in 0.4 mm, 31% in 0.8 mm, 33% in 2.5 mm [Ca2+]e, and 30% in 1 mm [Ca2+]e with 0.1 mm internal BAPTA (Fig. 5).
To provide additional evidence for the assertion that the extent of evoked MVR is determined by the opening of multiple Ca channels at an AZ, we evoked EPSCs using a different experimental protocol. The presynaptic RB was depolarized in 1 mm Ca2+ to −50 mV for 1.5–2 ms to activate few Ca channels; EPSCs were evoked during the tail Ca current that was elicited (Fig. 6). This protocol generated small Ca currents (3.6 ± 0.2 pA, reflecting the opening of ∼0.6 channels/AZ; n = 4), and failures of transmission were seen in ∼50% of trials. Evoked events were largely monophasic (i.e., they exhibited a rising phase with no obvious inflections and a smooth, monoexponential decay), but significant jitter in the timing of individual synaptic events was observed. The extent of this jitter is obvious when individual EPSCs are averaged after being aligned at their starting points: the resultant trace is larger and faster to rise and decay than an averaged trace generated without alignment of individual events (Fig. 6Bi).
Despite the jitter in the timing of the exocytotic events, individual EPSCs rose rapidly and had waveforms indistinguishable from quantal mEPSCs despite their being larger on average (quantal content = 1.2 ± 0.1 quanta; n = 4 recorded pairs). This is evident in a comparison of the aligned and averaged EPSC and mEPSC waveforms (aligned EPSC vs mEPSC: 10–90% rise time = 0.4 ± 0.1 vs 0.3 ± 0.1 ms, p = 0.22 by Mann–Whitney U test; τdecay = 1.0 ± 0.2 vs 0.8 ± 0.1 ms, p = 0.23; n = 4 recorded pairs) (Fig. 6B). This suggests the action of coordinated MVR, as has been described previously (Singer et al., 2004).
Further, for each recording EPSC amplitudes were normalized to the average mEPSC amplitude, and data from multiple recordings were pooled to generate normalized mEPSC and EPSC amplitude histograms (Fig. 6C). When we assayed the area of the EPSC amplitude histogram that did not include the mEPSC histogram, we found it to be 30%. This is close to the value of 26% predicted by the Poisson distribution of open Ca channels at AZs when the average number of open channels is ∼1/AZ.
Because ∼70% of the evoked events that we recorded appeared to reflect the release of single vesicles, the waveform of the averaged EPSC is dominated by the time courses of quantal events. Therefore, we wished to confirm that multiquantal EPSCs do not have a markedly different time course from uniquantal EPSCs. We did this by examining the waveforms of individual evoked and spontaneous (quantal) EPSCs (Fig. 7). We plotted the relationship between rise time (10–90%) and amplitude for EPSCs evoked by either small presynaptic voltage steps (e.g., Fig. 6) or presynaptic ramps (e.g., Fig. 4) as well as for the mEPSCs recorded in the corresponding experiments.
By comparing amplitude–rise time relationships of EPSCs and mEPSCs (Fig. 7A,B) and rise-time histograms of EPSCs and mEPSCs (Fig. 7C), it is apparent that the majority of EPSCs (both step evoked and ramp evoked) have rise times equivalent to those of mEPSCs. A subset of evoked events rose slightly more slowly than did mEPSCs, making the EPSC and mEPSC rise-time distributions statistically different (p ≪ 0.05 by Mann–Whitney U test). The largest EPSCs, however, were not uniformly slower than uniquantal events.
To support this conclusion, we examined ramp-evoked EPSCs in some detail. Of the 886 recorded EPSCs, 241 (27%) had quantal contents >2.5. The average rise time of these events was 0.3 ± 0.1 ms (mean ± SD; compared with 0.3 ± 0.1 ms for the events with quantal content <2.5; the average mEPSC rise-time = 0.3 ± 0.1 ms). Only 12/241 large, multiquantal EPSCs had rise-times >0.5 ms (>2 SDs above mean) (Fig. 7D, shaded area). This represents only 5% of the large EPSCs (and 1% of the total). These large, slower EPSCs were evoked at all membrane potentials >−50 mV (the threshold for MVR) and <−45 mV (the most depolarized potential reached by the ramp); they did not occur only at the end of the presynaptic voltage ramp (−45 mV) where the release rate was the highest, and EPSCs often were superimposed upon each other (Fig. 7D). Thus, from this analysis we conclude that the multiquantal EPSCs that we recorded reflect multivesicular release that is coordinated on a time scale <100–150 μs (2–3 sampling intervals at our sampling rate of 20 kHz); this is consistent with a previously published study (Singer et al., 2004).
Discussion
Our study elucidates a synaptic mechanism—nanodomain control of exocytosis—that underlies the physiological behavior of the RB synapse. Nanodomain control broadens the operating range of the synapse by generating a near-linear relationship between presynaptic membrane potential and exocytosis. Further, it permits a transition from uniquantal to multiquantal release to occur when multiple Ca channels/AZ open; this likely serves to increase synaptic gain at visual threshold. Importantly, MVR is not elicited by the opening of a single Ca channel.
Inferring the distribution of Ca channels at the presynaptic AZ
Approximately five Ca channels are associated closely with each docked vesicle at the RB AZ (Raviola and Raviola, 1982; von Gersdorff et al., 1998). As the RRP size at each AZ is approximately eight to nine vesicles, 45–50 Ca channels may be located at each AZ (data not shown) (Singer and Diamond, 2006; Zhou et al., 2006). Because approximately three channels/AZ open at the peak of a Ca tail current (Fig. 3), Popen,max for these channels must be quite low (∼5–10%). This is consistent with a study of the frog neuromuscular junction, another synapse at which few or single Ca channels control the release of single vesicles (Shahrezaei et al., 2006). During a physiological depolarization, then, only one or two channels/AZ will open coincidently.
Colocalization of Ca channels and vesicles is consistent with a synapse at which release sites are controlled by the opening of one or few Ca channels (Stanley, 1993; Brandt et al., 2005; Fedchyshyn and Wang, 2005; Shahrezaei et al., 2006; Bucurenciu et al., 2010). A previous study provides evidence for such colocalization in RB terminals: exocytosis at this synapse is largely insensitive to the exogenous Ca2+ chelators BAPTA and EGTA (Singer and Diamond, 2003). Here, two novel pieces of evidence for close coupling between Ca channels emerge (Figs. 4, 5). One, exocytosis is evoked reliably at presynaptic voltages sufficient to open only a single Ca channel at a subset of AZs. Two, the percentage of evoked events that are multiquantal does not increase with Ca2+ influx, indicating that Ca2+ does not act at a distance from its site of entry. In this respect, Ca channel-release site coupling at the mammalian RB synapse differs from that of the well-studied goldfish retinal giant bipolar cell synapse, at which exocytosis of individual vesicles requires the opening of multiple (∼5) channels (von Gersdorff and Matthews, 1997; von Gersdorff et al., 1998; Coggins and Zenisek, 2009).
We used simple simulations to assist in the interpretation of the data presented and to provide evidence that the combination of few open Ca channels located near a small RRP accounts for the dynamics of release from the RB terminal (supplemental Fig. 3, available at www.jneurosci.org as supplemental material). It is important to note that our observation that the opening of single Ca channels can activate individual release sites does not preclude the possibility that [Ca2+] domains arising from different channels may overlap (Stanley, 1993, 1997; Shahrezaei et al., 2006). Indeed, under conditions in which the RRP is full and approximately five presynaptic Ca channels are open (Figs. 1, 2) (e.g., when exocytosis is evoked by a tail Ca current), the mean distance between open channels is <20 nm, the average radius of a nanodomain generated by the opening of a single channel (supplemental Fig. 3, available at www.jneurosci.org as supplemental material). When only two channels/AZ open simultaneously, though (e.g., Figs. 4, 6), the mean distance between open channels is increased to 124 nm. Under this condition, which occurs at membrane potentials in the physiological operating range of the presynaptic terminal, <4% of open channels are within 20 nm of each other. Consequently, signaling during visual processing likely depends primarily on [Ca2+] nanodomain control of release sites.
Mechanisms of MVR
Coordinated MVR from auditory hair cells, rods, and RBs has been described (Glowatzki and Fuchs, 2002; Singer et al., 2004; Suryanarayanan and Slaughter, 2006; Li et al., 2009). The mechanism(s) underlying coordinated MVR are uncertain, and a universal one may not exist. For example, coordinated MVR from amphibian rods requires release of Ca2+ from internal stores (Suryanarayanan and Slaughter, 2006); store-mediated MVR has been observed in studies of cerebellar synapses but not in studies of auditory hair cell synapses (Llano et al., 2000; Neef et al., 2007).
Because the opening of single Ca channels does not evoke MVR even when Ca2+ flux through these channels saturates the vesicular release machinery (Figs. 1, 4), [Ca2+] must be elevated over an area larger than the domain of a channel to elicit MVR. Consistent with this notion, Ca2+-dependent coordinated MVR occurs at RB synapses during asynchronous release after the closure of Ca channels, at which time channel micromains have dissipated but intraterminal [Ca2+] remains elevated (Singer et al., 2004). That the number of predicted multichannel openings is quite similar to the observed number of multiquantal evoked events (∼30%) (Figs. 5, 6) indicates that the coordinating event requires the coincident elevation of [Ca2+] at multiple release sites. This mechanism, however, does not explain the precise timing of MVR (Fig. 6, 7): evoked multiquantal events have essentially the same time course as uniquantal mEPSCs though they exhibit significant intertrial jitter in their timing (Fig. 6, 7). Exocytotic events occurring at independent release sites, however, should exhibit jitter in their timing, and jitter is thought to arise downstream of Ca2+ binding to the release machinery (Diamond and Jahr, 1995; Isaacson and Walmsley, 1995).
Compound fusion, or the fusion of multiple vesicles to each other before a single exocytotic event, is a mechanism that can account for the precise timing of MVR. Direct evidence for compound fusion at a neuronal AZ, however, is rare. In a study of transmission at the Calyx of Held, He et al. (2009) observed an increase in quantal amplitude with no change in EPSC time course after long (up to 30 s) periods of presynaptic stimulation with either high-frequency action potential trains or KCl application. This phenomenon was interpreted to reflect compound fusion, a suggestion supported by the demonstration of a stimulation-induced increase in vesicle diameter. Similarly, increased vesicle size indicating compound fusion has been observed in the goldfish giant bipolar cell terminal after prolonged stimulation (Matthews and Sterling, 2008).
Though we have no direct experimental evidence supporting or discounting the contribution of compound fusion to coordinated MVR, three observations argue indirectly against compound fusion being the sole underlying mechanism. One, coordinated MVR follows the opening of only two Ca channels/AZ (Figs. 4, 6); our experimental paradigm is very different from the strong stimulation used in the aforementioned studies (Matthews and Sterling, 2008; He et al., 2009). It is improbable that neighboring channels always open together to promote fusion of adjacent vesicles, and the opening of two channels is unlikely to elevate [Ca2+] globally to promote compound fusion reliably. Two, though we would expect that compound fusion would increase with Ca influx into the RB terminal, neither the amplitude of multiquantal EPSCs (Fig. 5) nor the mEPSC amplitude (data not shown) (Singer et al., 2004) increases with [Ca2+]e. Three, it is unlikely that the appearance of multiquantal events in the EPSC distribution would be predicted by simple binomial statistics if vesicles fused with each other in addition to the plasma membrane (Singer et al., 2004). Thus, the precise mechanism of coordinated MVR at the RB synapse remains to be discovered. Though compound fusion cannot be discounted, other mechanisms also should be considered.
Relevance to scotopic signal processing
Signal gain in the neural circuitry downstream of rods appears to be controlled at the RB–AII synapse: at low light intensities—<1 rhodopsin isomerization (R*)/rod/s—the synapse amplifies RB responses and then reduces its gain as a result of synaptic depression (Dunn et al., 2006; Dunn and Rieke, 2008). The voltage dependence of the transition from uniquantal to multiquantal release that we describe here (Fig. 4) is well matched to serve the operational needs of the RB synapse. In the dark-adapted retina, the RB rests at −60 mV, the presynaptic holding potential in our experiments (Dunn and Rieke, 2008). EPSPs evoked in RBs at light intensities <1 R*/rod/s are not well characterized but are likely 5–10 mV (based on light-evoked EPSCs of 5–10 pA and an input resistance of ∼1 GΩ) (Field and Rieke, 2002; Dunn and Rieke, 2008). Depolarization 5–10 mV from rest moves the RB membrane through the foot of the presynaptic Ca channel I–V relationship (a highly nonlinear range), making evoked exocytosis multiquantal as the probability of multiple Ca channel openings/AZ increases. The transition to MVR can provide significant amplification of the synaptic signal as the RB terminal traverses the voltage range likely to be covered by light responses elicited when rods absorb only single photons. At higher light intensities, RB output varies linearly with membrane potential: presynaptic voltage changes on the linear portion of the Ca channel I-V relationship, and exocytosis varies linearly with the number of activated Ca channels to provide a wide dynamic range for signaling.
Footnotes
This work was supported by National Institutes of Health (NIH) Grant EY-017836, National Science Foundation Grant 0551852, the Alfred P. Sloan Foundation (to J.H.S.) by NIH Grant EY-019828 (T.J.), and by an unrestricted grant from Research to Prevent Blindness to the Department of Ophthalmology at Northwestern University. We thank Drs. W. Grimes, M. Martina, and C. Ratliff for helpful discussion; Drs. E. Mugnaini, L.-G. Wu, and C. Woolley for reading the manuscript; Drs. R. Wong and N. Vardi for the gift of Grm6-GFP mice; and P. Chung and V.J. Dudley for technical assistance.
- Correspondence should be addressed to Joshua H. Singer, Department of Ophthalmology, Northwestern University Feinberg School of Medicine, 303 E. Chicago Ave., Tarry 5-715, Chicago, IL 60611. j-singer{at}northwestern.edu