Reliability of a Fly Motion-Sensitive Neuron Depends on Stimulus Parameters

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The Journal of Neuroscience, December 1, 2000, 20(23):8886-8896

Reliability of a Fly Motion-Sensitive Neuron Depends on Stimulus Parameters
Anne-Kathrin Warzecha, Jutta Kretzberg, and Martin Egelhaaf
Lehrstuhl für Neurobiologie, Fakultät für Biologie, Universität Bielefeld, D-33501 Bielefeld, Germany

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The variability of responses of sensory neurons constrains how reliably animals can respond to stimuli in the outside world.We show for a motion-sensitive visual interneuron of the fly thatthe variability of spike trains depends on the properties of themotion stimulus, although differently for different stimulus parameters.(1) The spike count variances of responses to constant and todynamic stimuli lie in the same range. (2) With increasing stimulussize, the variance may slightly decrease. (3) Increasing patterncontrast reduces the variance considerably. For all stimulus conditions,the spike count variance is much smaller than the mean spike countand does not depend much on the mean activity apart from verylow activities. Using a model of spike generation, we analyzedhow the spike count variance depends on the membrane potentialnoise and the deterministic membrane potential fluctuations atthe spike initiation zone of the neuron. In a physiologicallyplausible range, the variance is affected only weakly by changesin the dynamics or the amplitude of the deterministic membranepotential fluctuations. In contrast, the amplitude and dynamicsof the membrane potential noise strongly influence the spike countvariance. The membrane potential noise underlying the variabilityof the spike responses in the motion-sensitive neuron is concludedto be affected considerably by the contrast of the stimulus butby neither its dynamics nor itssize.

Key words: reliability; variability; motion vision; neural coding; spike generation; model; fly

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

All information an animal is able to acquire about its environment is contained in the activity of its nerve cells. Therefore,the variability of neuronal responses constrains how reliablystimuli can be perceived or responded to. In cortical visual interneurons,spike count variances have been found to be in the order of themean spike count (Tolhurst et al., 1983; Vogels et al., 1989;Britten et al., 1993; Barberini et al., 2000). Smaller spike countvariances have been observed at more peripheral stages of thevertebrate visual system (Levine et al., 1988, 1992; Berry etal., 1997; Reinagel and Reid, 2000) and in motion-sensitive neuronsof the fly (de Ruyter van Steveninck et al., 1997; Warzecha andEgelhaaf, 1999).

In visual neurons, a given activity can usually be elicited by various combinations of stimulus parameters. For example, theoutput of motion-sensitive visual interneurons may depend on thesize, the contrast, and the velocity of the stimulus. An extendedpattern with a small contrast may elicit the same response asa smaller pattern with a high contrast. Moreover, stimuli withtemporally modulated velocity might lead, at a certain responsephase, to the same response level as a constant velocity stimulus.Because in these situations the spatiotemporal activity distributionacross the synaptic inputs of the neuron may differ considerably,the variability in the resulting responses may also differ. Apartfrom studies that explicitly investigated whether the stimulusdynamics affects neuronal variability (Berry et al., 1997; deRuyter van Steveninck et al., 1997; Bura $c$ as et al., 1998; Warzechaand Egelhaaf, 1999), there are only few studies on the dependenceof neuronal variability on the stimulus conditions (Dijk and Ringo,1987; Croner et al., 1993).

Therefore, we analyze the stimulus dependence of the across-trial variance of the spike activity of the H1 neuron in the flyvisual system. The H1 neuron, as well as other so-called tangentialcells (TCs), of the fly have been widely used for investigatingneuronal processing of visual motion information (for review,see Hausen and Egelhaaf, 1989; Egelhaaf and Borst, 1993; Egelhaafand Warzecha, 1999) and, in particular, the reliability of neuralcoding (de Ruyter van Steveninck and Bialek, 1988, 1995; de Ruytervan Steveninck et al., 1997; Haag and Borst, 1997; Warzecha andEgelhaaf, 1997, 1999; Warzecha et al., 1998). Our electrophysiologicalanalysis is supplemented by model simulations, which will formthe basis for interpreting the experimental results. The simulationsare based on a phenomenological model of spike generation thatwas adjusted to account for the response properties of the H1neuron (Kretzberg et al., 2000). In the simulations, the postsynapticmembrane potential is varied systematically to analyze the determinantsof the resulting spike responses. The spike count variance willbe shown not to be determined unambiguously by the mean spikeactivity but to depend also on the visual input that induces agiven activity level. Irrespective of this stimulus dependence,the spike count variance will be shown to be considerably smallerthan the mean spike count for all stimulusconditions.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Preparation and electrophysiology. For electrophysiological experiments, female blowflies of the genus Calliphora were obtainedfrom our laboratory stocks. To avoid inbreeding, the stocks wereregularly refreshed by animals caught outside. The animals weredissected as described previously (Warzecha and Egelhaaf, 1997).The experiments were performed at room temperature (19-22°C).Experiments were done in compliance with institutional guidelinesand those of the Society forNeuroscience.

The H1 neuron can be identified unambiguously on the basis of its preferred direction of motion and the location of its extendedoutput region (Eckert, 1980; Hausen, 1981). The activity of theH1 neuron was recorded extracellularly with tungsten electrodesin its output region. The electrode tips were sharpened electrolyticallyand insulated with varnish. They had resistances between 2 and8 M $Omega$ . Recorded signals were processed by standard electrophysiologicalequipment. Spikes were converted into pulses of fixed height andduration, which were fed at a rate of 1 kHz into a personal computerthrough an analog-to-digital converter of an input-output card(2801A; Data Translation Inc., Marlboro, MA). Only extremely wellisolated H1 signals were recorded, so that our data were freeof noise introduced at the level of data acquisition. The programsfor data acquisition were written in ASYST (Keithley Instruments,Cleveland,OH).

Visual stimulation. Moving square wave gratings were used as stimuli (spatial wavelength, 18°; mean luminance, 7.9 cd/m²; contrast as specified in figure legends) and displayed on acathode ray tube (model 608; Tektronix, Wilsonville, OR) at aframe rate of 183 Hz by an image synthesizer (Picasso; InnisfreeInc., Cambridge, MA). In previous investigations, it was ensuredthat spikes do not time lock to this frame rate (Warzecha et al.,1998; Warzecha and Egelhaaf, 1999). The image synthesizer wascontrolled by a personal computer. The center of the monitor wasat an azimuth/elevation of 45°/0°, with 0°/0° referring to thefrontal midline of the fly. The front edge of the monitor screenwas at an azimuthal position of 0°. The horizontal extent of thestimulus pattern was 90°, and its vertical extent was varied andwill be given in the figure legends. Irrespective of the verticalextent, the vertical position of the pattern was always centeredat an elevation of 0° in the receptive field of the H1 neuron.Data acquisition was started with the frame synchronization signalof the image synthesizer. Four different data sets were obtainedby varying the vertical extent of the stimulus pattern, its contrast,and/or its velocity. For each data set, a different sample offlies was used. For each fly, all visual stimuli used to obtainthe particular data set were presented in a pseudorandom order,so that each stimulus was presented once before the next sequencestarted. Two types of pattern motion dynamics were used: constantand randomly fluctuating velocity. For constant velocity stimuli,the pattern was moved in the preferred direction of the cell for2.5 sec. To obtain a dynamic velocity stimulus, white-noise velocityfluctuations were generated according to a gaussian distribution.The resulting velocity trace was low-pass filtered with a cutoffat 80 Hz to avoid aliasing caused by the frame rate limit. Afterlow-pass filtering, the SD of the velocity trace was 0.12°/msec.For the dynamic velocity fluctuations, pattern motion lasted for5 sec. Presentation of motion stimuli was interrupted by an intervalof 6.5 sec. During this interval, the stimulus pattern was homogeneouswith a luminance of 7.9 cd/m² corresponding to the mean luminance of all moving stimuli thatwere used in the experiments. For the experiments with stimuliof variable vertical extent, the mean luminance was presentedin all parts of the screen that were not covered by the motionstimulus.

Data evaluation. For constant velocity stimuli, only 1000 msec of the response starting 1500 msec after the onset of motionwere evaluated to analyze primarily the steady-state responseinstead of the onset transients. For dynamic velocity stimuli,4900 msec starting 100 msec after the onset of motion were evaluated.For each stimulus condition and each cell, 40-60 consecutive trialswere taken for quantitativeanalysis.

The mean spike count as well as the spike count variance were determined within time windows of variable size. The shortesttime window used was 20 msec because shorter time windows leadto results that hardly reflect the variability of the responses(Warzecha and Egelhaaf, 1999). On the other hand, if the timewindows are too long, they average out activity modulations asmay be elicited by dynamic motion stimuli. Because the dependenceof the variance on the mean activity of the cell may differ fordifferent time windows, results will be displayed for time windowsof 20 and 100 msec size. We thus cover a large range of time windowsused in previous studies on the variability of the fly H1 neuron(de Ruyter van Steveninck et al., 1997; Warzecha and Egelhaaf,1999). The mean spike count and the corresponding spike countvariance were evaluated across trials in consecutive time windowsthat were shifted by 10 msec. Hence, consecutive 20 or 100 msectime windows overlapped by 10 or 90 msec, respectively. This evaluationwas done separately for each cell, each stimulus condition, andeach size of the time window. For dynamical velocity stimulation,the mean spike count was assigned to activity classes with a widthof either 0.4 spikes/20 msec window or 2 spikes/100 msec window.Variances of each cell were averaged if the corresponding meanspike count fell into the same activity class. The variances associatedwith a given activity class, pattern size, and time window wereaveraged, irrespective of the response phase during which theactivity was attained. These values were then averaged over thecells contributing to one data set. Only those activity classesand corresponding variances will be shown to which at least fourcellscontributed.

During constant stimulation, the activity stays almost constant and modulates only weakly with the temporal frequency of patternmotion. The activity thus spreads only over very few activityclasses. The variances were therefore not averaged within differentactivity classes. Only a single variance value was determinedtogether with the corresponding mean spike count for each stimuluscondition and cell. These variances and mean spike counts werethen averaged over all cells of a dataset.

The variance of the responses strongly depends on whether the neuronal activity shows a systematic trend over the recordingperiod. We selected by the following procedure only those datafor further analysis that did not show a strong trend. The meanactivity during stimulation with any of the motion stimuli presentedto a given cell was not allowed to change by more than 1 spike/secand per trial, as judged from a regression line through the meanactivities plotted over the number of trials. Therefore, 13 of52 cells had to bediscarded.

Model simulations. To investigate the determinants of the spike count variance, we used a phenomenological threshold modelthat transforms time-dependent membrane potential fluctuationsinto sequences of action potentials. These sequences will be comparedwith the spike responses of the H1 cell. The details of the modelhave been described previously (Kretzberg et al., 2000). In brief,for every time step, the membrane potential is compared with aspike threshold that depends on both the time elapsed since theprevious spike occurred and the temporal changes of the membranepotential. A spike is fired when the membrane potential crossesthreshold. The threshold is calculated according to the followingequation:

with t_i indicating time step, s indicating time elapsed since the previous spike, $gamma$ ^ref indicating absolute refractory period, and $theta$ ₀ indicating constantbasis threshold.

is the influence of the relative refractoriness with weight constant $eta$ ₀.

is the influence of the membrane potential changes within the last T data points, with weight constant $rho$ ₀ and membrane potentialU(t_i).

For a constant membrane potential, the term $eta$ (s) causes the threshold to decrease to the constant value $theta$ ₀ after the absoluterefractory period $gamma$ ^ref. When the membrane potential varies, the resulting thresholdis influenced by the term $rho$ (t). It represents the weighted andsign-inverted sum of the slopes between the last T membrane potentialvalues and the reference potential U(t_i) at time t_i. The thresholddecreases while the membrane potential depolarizes, and it riseswhile U(t) hyperpolarizes. The steeper the membrane potentialrises or falls, the more the threshold is influenced by the term $rho$ (t). This term has been included in the model, because fast depolarizingchanges in the membrane potential are generally found to be moreeffective in eliciting a spike than slow ones (Johnston and Wu,1995; Azouz and Gray, 2000).

The model cell was fed by membrane potential fluctuations as they were elicited by motion stimuli with random velocity fluctuationsin a fly TC (HS cell). This neuron has a similar input organizationas the H1 neuron and responds to motion stimulation with pronouncedmembrane potential changes, which are assumed to closely reflectthe pooled postsynaptic potentials of many retinotopically organizedmotion-sensitive elements (for a detailed discussion of this aspect,see Kretzberg et al. 2000). These potentials are assumed to besimilar to the postsynaptic potentials of the H1 neuron. Methodologicaldifficulties render it impracticable to directly record the postsynapticpotentials of the H1neuron.

The input to the model of spike generation consisted of two components, a deterministic and a stochastic one. (1) The deterministiccomponent of the membrane potential was derived from the time-dependentmembrane potential of the HS cell averaged over 100 responsesto identical dynamical motion stimulation. The averaging was assumedto eliminate stochastic membrane potential fluctuations. The averagewas sign-inverted to account for the opposite preferred directionsof the HS and the H1 cell and taken to represent the stimulus-inducedresponse component. The response traces of the HS cell that formedthe basis of the model simulations were obtained in a previousstudy under one given stimulus condition (Warzecha et al., 1998,their Fig.3).

(2) The stochastic component of the membrane potential was computed individually for each trial as a series of gaussian distributedrandom numbers that was low-pass filtered. A gaussian probabilitydistribution fitted quite well the experimentally determined distributionof the membrane potential noise. By adopting the SD of the noisefrom experimental data and by temporally filtering the seriesof random numbers, the power spectrum of the stochastic componentwas fitted to the power spectrum of the experimentally determinedmembrane potential noise of the HS cell (Warzecha et al., 1998;Kretzberg et al., 2000). The terms "stochastic component" and"membrane potential noise" will both be used in the followingassynonyms.

The model simulations allowed us to systematically vary the deterministic and the stochastic response components separatelyfrom each other. This was done by scaling the amplitude of eithercomponent with a factor or by stretching their time scale (fordetails, see Results and figure legends). Both components wereadded and then fed into the spike generation mechanism. If notspecified otherwise, 500 different stochastic sequences with thesame statistical properties were used for every analysis. Eachsequence lasted for 2960msec.

The model parameters were adjusted so that the resulting spike trains fit, on average, the spike trains of the H1 cell whenstimulated with the same dynamic motion stimuli as the HS cell(for details, see Kretzberg et al., 2000). With the parametersets obtained in this way, the relevant features of the H1 cellresponse, such as the time-dependent spike frequency histogram,as well as its highly correlated activity with another spikingneuron that receives partly the same input can be readily explained(Kretzberg et al., 2000). The model simulations presented herewere done with five parameter sets, identical to those used ina previous paper (Kretzberg et al. 2000). All parameter sets leadto qualitatively the same results. The data that are shown inFigures 6-9 were obtained with the following parameters: $gamma$ ^ref = 2 msec, $theta$ ₀ = 1 mV, $eta$ ₀ = 20 msec · mV, $rho$ ₀ = 3.75, and T = 3data points. A temporal resolution of 2.7 kHz was used for themodelsimulations.

The simulated data were evaluated in the same way as the experimental ones. The model simulations and all evaluation routineswere implemented in Matlab 5.3 (The MathWorks Inc., Natick,MA).

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Experimental analysis of stimulus dependence of the variance

The H1 neuron integrates the output signals of many local motion-sensitive elements with basically the same direction selectivity.Therefore, it responds selectively to motion in a particular directionin large parts of the visual field of one eye. It increases itsspike activity above the resting level during back-to-front motion("preferred direction") and decreases its spike rate during front-to-backmotion ("null direction"). Because the spontaneous firing rateof the H1 neuron is low, the cell usually stops firing duringnull direction motion. When stimulated with random velocity fluctuations,the spike frequency of the H1 cell is modulated in time. The timecourse of these response modulations follows to some extent thevelocity fluctuations, although it is not proportional to thevelocity, in particular when the direction of pattern velocitychanges rapidly (Egelhaaf and Reichardt, 1987; Haag and Borst,1997) (for review, see Warzecha and Egelhaaf, 2000).

Variation of pattern size
Spike frequency histograms of responses to the same random velocity fluctuations of two patterns of different size are shownin Figure 1A. The histograms were determined with time windowsof 20 msec. The response amplitude decreases with decreasing patternsize. Nonetheless, the time course of the response is very similarfor the different pattern sizes (Fig. 1A, compare dashed lines,solid lines). Analogous to the mean spike count, the across-trialvariance in the spike count can be plotted as a function of time(Fig. 1B). Here the same 20 msec time windows were used as forthe spike frequency histograms in Figure 1A. The variance is notconstant during dynamic velocity stimulation but rather modulatesin time. The modulations follow, at least to some extent, thefluctuations of the mean spike count. Nonetheless, the large differencesin the amplitudes of the time-dependent spike count obtained withsmall and large stimulus patterns (Fig. 1A) are not reflectedin corresponding differences in the time-dependent variance profiles(Fig. 1B). Rather, the variances obtained with the different patternsizes are quite similar. The data were further evaluated by determiningthe dependence of the across-trial variance on the mean spikecount. For the 20 msec time window, the spike count variance issmall at very low activities compared with the variance obtainedin higher activity classes (Fig. 1C). For activities above ~0.6spikes/20 msec window (i.e., 30 spikes/sec), the variance doesnot increase further. Within a given activity class, the variancesdo not much differ for stimulus patterns of different size (Fig.1C). In contrast, when calculated within 100 msec time windows,there are slight differences in the variances of responses elicitedby stimuli of different size. In the low-activity range, the varianceis smallest for the largest stimulus pattern (Fig. 1D). For thelargest pattern, the variance increases slightly with increasingmean activity. For smaller patterns, such an increase can onlybe observed in the low-activity range. Overall, the spike countvariance does not strongly depend on the activity of the neuron.The spike count variances obtained when the H1 neuron was activatedby constant velocity motion were in the same range as the oneselicited with the same pattern moving at continually changingvelocities (Fig. 1, compare D, E).

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Figure 1. Response variability of the H1 neuron obtained for the motion of stimulus patterns with variable size. See insets for the vertical extent of the pattern. Altogether, 457 individual response traces of eight H1 cells were analyzed. The mean resting activity was 9.1 spikes/sec. Pattern contrast, 20%. A, Section of the mean time course of responses to band-limited white-noise velocity fluctuations. Spikes were counted in each trial within consecutive time windows of 20 msec time-locked to the onset of motion. Consecutive time windows overlapped by 10 msec. Spike counts in corresponding time bins were averaged across trials. Time 0 denotes the onset of the stimulus. B, Mean time course of the across-trial variance of the spike count obtained within the same section of 20 msec time windows. C, Spike count variance as a function of the mean spike count within 20 msec time windows obtained for band-limited white-noise velocity fluctuations (see Materials and Methods). D, Spike count variance as a function of the mean spike count within 100 msec time windows obtained for band-limited white-noise velocity fluctuations. E, Spike count variance as a function of the mean spike count within 100 msec time windows obtained for constant velocity stimulation. The temporal frequency of pattern motion amounted to 2 Hz. C-E, Error bars denote SEMs across trials. C, D, Although these experiments were made on eight cells, a variable number of cells (4-8) contributed to each data point because not every cell covered the entire activity range.

Variation of pattern contrast
Changing the contrast of the pattern does not much alter the time course of the response but influences mainly the responseamplitude (Fig. 2A). The time-varying variance of responses tothe high-contrast pattern assumes, for most of the time, slightlylower values than the variance of responses to the low-contraststimulus (Fig. 2B). When plotting the variance as a function ofthe mean activity, it becomes evident that the variance differsfor different stimulus contrasts, at least in the activity rangeof up to 2.6 spikes/20 msec time window (i.e., up to 130 spikes/sec)(Fig. 2C). For a given activity class, higher contrasts lead tosmaller variances (Fig. 2C). This difference is more pronouncedwhen the variance is evaluated in 100 msec than when 20 msec timewindows are used (Fig. 2, compare C, D). Hence, pattern size andpattern contrast seem to affect the spike count variance in theH1 cell in a different way. The variances obtained when the velocityof pattern motion was constant are in the same range as thoseobtained with randomly fluctuating velocities for all three patterncontrasts tested (Fig. 2, compare D, E).

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Figure 2. Response variability of the H1 neuron obtained for the motion of stimulus patterns with variable contrast. See insets for pattern contrast. Altogether, 530 individual response traces of 9 H1 cells were analyzed. The mean resting activity of the H1 neuron of this sample of flies was 10.1 spikes/sec. Vertical extent of pattern, 20.8°. Data were evaluated in the same way as described in the legend of Figure 1. A, Section of the mean time course of responses to band-limited white-noise velocity fluctuations within 20 msec time windows. B, Mean time course of the across-trial variance of the spike count obtained within the same section of 20 msec time windows. C, Spike count variance as a function of the mean spike count within 20 msec time windows obtained for band-limited white-noise velocity fluctuations. D, Spike count variance as a function of the mean spike count within 100 msec time windows obtained for band-limited white-noise velocity fluctuations. E, Spike count variance as a function of the mean spike count within 100 msec time windows obtained for constant velocity stimulation. The temporal frequency of pattern motion amounted to 2 Hz. C-E, Error bars denote SEMs across cells. C, D, Between four and nine cells contributed to each data point.

Variation of the velocity of pattern motion
The steady-state response amplitude of the H1 cell to constant velocity motion first increases with increasing velocity, reachesan optimum, and then declines again (Egelhaaf and Borst, 1993b).In the tested velocity range, the largest responses were obtainedfor small velocities (Fig. 3). With increasing activity, the varianceinitially increases and then decreases again. Hence, when thevelocity of a stimulus is changed to alter stimulus strength,the spike count variance does not monotonically increase withincreasing activity of the cell. As is the case for the experimentsin which pattern size or contrast were varied, the spike countvariance stays much smaller than the mean spike count.

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Figure 3. Response variability of the H1 neuron to constant velocity stimuli covering a range from 9 to 576°/sec. The vertical extent of the pattern was 20.8°, and its contrast amounted to 20%. Altogether, 460 individual response traces of eight H1 cells were analyzed. The mean resting activity was 15.3 spikes/sec. Error bars denote SEMs across eight cells.

Variation of pattern contrast and pattern size
In the next step of the analysis, we compared the variances obtained for different stimulus conditions that were chosen tolead with very similar spike frequency histograms. One stimuluspattern had a larger vertical extent but a lower contrast thanthe other. Both patterns were moved with the same velocity profile.The resulting spike frequency histograms (Fig. 4A) were at leastmuch more similar than the spike frequency histograms that wereobtained when either only pattern size (Fig. 1A) or pattern contrast(Fig. 2A) were varied. Moreover, both patterns led also to nearlythe same mean response amplitude when they were moved at a constantvelocity (p > 0.5; t test) (Fig. 4E). Despite the close correspondenceof both the time course and the mean amplitude of the responses,the spike count variance across trials was significantly largerfor the large low-contrast pattern than for the smaller high-contrastpattern (Fig. 4C-E, see figure legend for statistical details).

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Figure 4. Response variability of the H1 neuron obtained for the motion of stimulus patterns with variable contrast and vertical extent. See insets for stimulus conditions. Altogether, 728 individual response traces of 14 H1 cells were analyzed. The mean resting activity was 11.4 spikes/sec. Data were evaluated in the same way as described in the legend of Figure 1. A, Section of the mean time course of responses to band-limited white-noise velocity fluctuations within 20 msec time windows. B, Mean time course of the across-trial variance of the spike count obtained within the same section of 20 msec time windows. C, Spike count variance as a function of the mean spike count within 20 msec time windows obtained for band-limited white-noise velocity fluctuations. To test whether the differences in the spike count variances are significant, a two-factor ANOVA was applied. The ANOVA was done for two subsets of the data because not all cells contributed to the large activity classes. Subset 1 contained the four smallest activity classes and 14 cells; subset 2 contained the eight smallest activity classes and six cells. The spike count variances for the large low-contrast pattern are significantly larger for both subsets (p < 0.01). D, Spike count variance as a function of the mean spike count within 100 msec time windows obtained for white-noise velocity fluctuations. As in C, a two-factor ANOVA was applied to two subsets of the data. Subset 1 contained the three smallest activity classes and 14 cells; subset 2 contained the seven smallest activity classes and five cells. The spike count variances for the large low-contrast pattern are significantly larger for both subsets (p < 0.01). E, Spike count variance as a function of the mean spike count within 100 msec time windows obtained for constant velocity stimulation. The temporal frequency amounted to 2 Hz. The spike count variance for the large low-contrast pattern is significantly larger than the spike count variance for the small high-contrast pattern (t test; p < 0.01). C-E, Error bars denote SEMs across cells. C, D, Between 4 and 14 cells contributed to each data point.

The results of Figure 4 go beyond those shown in Figures 1 and 2. In Figure 4, different spike count variances were obtained,although for each time interval almost the same response amplitudeswere induced by the different stimuli. Hence, even for a givenmean spike count and almost the same temporal profile of the responses,the spike count variance may greatly differ. Because pattern sizewas found to influence the spike count variability only little,it is concluded that the spike count variance is mainly influencedby pattern contrast, being largest for low-contraststimuli.

Variability between different cells
There is a large interindividual variability in the spike count variances. Even for a given stimulus condition they may differby a factor of up to ~3.5 independent of stimulus dynamics. Asa consequence of the large interindividual variability of thespike count variance, a quantitative comparison between differentdata sets is problematic, at least if these are not very large.For example, the data presented in Figures 1 and 2 were each obtainedfrom the individually identifiable H1 cell in a different sampleof either 8 or 9 flies, respectively. One dynamical and one constantmotion stimulus were the same for both data sets. Nonetheless,the corresponding data points shown in Figures 1C-E and 2C-E (filledtriangles) show considerable quantitative differences. This variabilityof the response properties between different animals and datasets underlines the importance to restrict quantitative comparisonsto responses obtained from the same sample ofcells.
On average, variances of responses to constant and to dynamical stimuli lie in the same range, although there are cells forwhich the variance of responses to constant stimuli is approximatelytwice as large as that of responses to dynamical stimuli and viceversa (Fig. 5). There is no obvious relationship between the ratioof the variances of responses to dynamical and constant stimulion the mean activity. Variances obtained with constant and thoseobtained with dynamical stimuli do not covary for any stimulusconfiguration used in the present study (t test, p > 0.05, 8 $<=$ N $<=$ 14).

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Figure 5. Variability between different H1 cells and stimulus conditions. The quotient between the mean spike count variance for dynamical and that for constant velocity stimulation is plotted as a function of the mean spike count during constant stimulation. The mean spike count and its variance during constant velocity stimulation were evaluated within 100 msec time windows for each cell and stimulus condition separately, as described in Materials and Methods. To obtain the mean spike count variances for dynamic stimulation, only those 100 msec time windows were taken into account for which the mean activity fell into the same activity range that was covered by constant velocity stimulation. The largest (smallest) mean spike count variance contributing to the figure amounted to 3.14 spikes²/100 msec (0.56 spikes²/100 msec) for constant stimulation and to 2.70 spikes²/100 msec (0.68 spikes²/100 msec) for dynamical stimulation. Data are part of those used for Figures 1, 2, and 4. Symbols indicate the different data sets. For each cell, two or three data points (depending on the data set) are shown, which were obtained by the different stimulus conditions.

Relationship between membrane potential fluctuations and spike count variability

The experimental analysis led to two major results that need to be further investigated. (1) Apart from very low spike rates,the across-trial variance is much smaller than the mean spikecount. (2) The response variance is affected in different waysby the size and the contrast of the stimulus pattern. Whereas,in a given activity class, the variance does not much depend onpattern size, it is significantly larger at low-pattern than athigh-patterncontrasts.

One way to explain these results is to relate them to the membrane potential and its fluctuations at the spike initiationzone of the H1 neuron. These membrane potential fluctuations canbe split up into two components. One component is induced deterministicallyby the stimulus. The other component varies across trials andwill be called stochastic. These membrane potential changes arenot easily accessible in the H1 neuron and cannot be systematicallyvaried in an experimental analysis. Therefore, model simulationswere performed to analyze what characteristics of the deterministicand the stochastic component may determine the dependence of thespike count variance on the mean spike count. In particular, weinvestigated how the amplitude and the dynamics of the deterministicand the stochastic component of the membrane potential influencethe spike countvariance.

The model simulations were based on a phenomenological time-dependent threshold model of spike generation that transformsmembrane potential fluctuations into sequences of action potentials.The model could be shown in a previous study to be sufficientto account for the time-dependent responses as well as for thereliability of the H1 neuron (Kretzberg et al. 2000). The deterministiccomponent of the membrane potential fluctuations fed into themodel was taken from experimental data of another TC in the fly'sbrain, an HS cell. The stochastic membrane potential componentwas simulated by band-limited gaussian white noise with a powerspectrum adjusted to the electrophysiologically determined membranepotential noise (see Materials and Methods; Kretzberg et al.,2000). HS cells mainly respond with graded changes in their membranepotential, which, in a first approximation, represent the summatedpostsynaptic potentials of their many local motion-sensitive inputelements. Apart from their response mode, HS cells respond tomotion stimuli in the preferred direction in basically the sameway as the H1 cell investigated above (Hausen, 1981; Warzecha,1994; Haag and Borst, 1997; Warzecha and Egelhaaf, 2000). To analyzethe determinants of the spike count variance, we systematicallyvaried in our model simulations the amplitude and the time courseof the deterministic membrane potential fluctuations as well asthe properties of the membrane potentialnoise.

Variation of the amplitude of the deterministic membrane potential component
A given mean membrane potential trace of an HS cell obtained during stimulation with random velocity fluctuations was usedin three different ways as input to the model, i.e., either inits original form or scaled in amplitude by a factor of either0.5 or 1.5. The properties of the superimposed membrane potentialnoise were identical for all three versions of the deterministicinput component. The resulting spike frequency histograms aremodulated over time in a similar way as the corresponding responsesof the H1 cell (data not shown) (but see Kretzberg et al., 2000).When the spike rate, determined in 100 msec time windows, is plottedas a function of the corresponding deterministic membrane potentialcomponent, an almost linear relationship between both variablesis obtained, irrespective of whether experimental or simulateddata are evaluated (Fig. 6A). Virtually the same spike count isobtained for a given amplitude of the deterministic component,independent of the scaling factor. In the simulations, the cellwas depolarized by up to 10 mV. Fly HS cells do not depolarizemuch more when recorded in their axon, even during strong visualstimulation. Because of the refractory properties of the modelneuron, the spike count will start to saturate when the cell isfurther depolarized (Fig. 7A). The largest hyperpolarization attainedduring visual stimulation were approximately $-$ 10 mV. In the H1cell as well as in the model cell, spikes are elicited even whenthe deterministic membrane potential component is negative relativeto the resting potential (0 mV) (Fig. 6A). In the model, suchevents are primarily attributable to stochastic membrane potentialfluctuations occasionally passing the threshold. These resultssuggest that the spike rate of the H1 neuron is approximatelyproportional to the membrane potential at its spike initiationzone for most of the range of postsynaptic potentials elicitedduring visual stimulation. A linear relationship between membranepotential and spike rate is in accordance with previous experimentalresults on fly TCs; the spike count in the H1 neuron and the averagemembrane potential of the HS cell depend in basically the sameway on visual stimulation (Hausen, 1981), and the mean time courseof the responses of both cell types is very similar during preferreddirection motion (Kretzberg et al., 2000, their Fig. 2). However,the linear relationship between membrane potential and spike countis in contrast to a strong saturation of spike activity that washypothesized for retinal ganglion cells even for relatively smalldepolarizations (Berry and Meister, 1998).

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Figure 6. Dependence of the response properties of a simulated spiking neuron on the amplitude of the deterministic membrane potential component. The deterministic component scaled with a factor of 1 corresponds to the unaltered membrane potential fluctuations of a tangential cell to dynamic motion stimulation averaged across 100 trials. It lasted for 2960 msec. A membrane potential of 0 mV corresponds to the resting potential of the tangential cell. The amplitude of the deterministic membrane potential component was increased and decreased by 50% (see insets). The stochastic membrane potential component was fitted to the experimental data (see Materials and Methods). The mean spike count and the spike count variance were determined across 500 individual response traces for each input condition. A, Dependence of the spike count on the deterministic membrane potential component for simulated and experimentally determined data (see inset). Note that different symbols superimpose. The mean deterministic component and the mean spike count were determined in 20 msec time windows. The mean deterministic membrane potential was assigned to activity classes with a width of 2 mV. Spike counts were averaged if the corresponding mean membrane potential fell into the same activity class. For the experimental data, 100 responses from an H1 neuron were evaluated. The neuron was stimulated with the same dynamic motion fluctuations as the HS cell used to determine the deterministic response component of the membrane potential. In another recording (data not shown), the mean spike count for each activity class of the membrane potential was slightly larger than that of the model cell. B, Spike count variance as a function of the mean spike count within 20 msec time windows. As for the experimental data (see Materials and Methods), the mean spike count was assigned to activity classes with a width of 0.4 spikes per time window. Spike count variances were averaged if the corresponding mean spike count fell into the same activity class. C, Spike count variance as a function of the mean spike count within 100 msec time windows. Consecutive time windows overlapped by 90 msec. The mean spike count was assigned to activity classes with a width of two spikes per time window. Spike count variances were averaged if the corresponding mean spike count fell into the same activity class.

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Figure 7. Dependence of the responses of a simulated spiking neuron on the dynamics of the deterministic component of membrane potential. To obtain the constant deterministic component, the membrane potential was set to constant values. To cover the entire response range of a tangential cell, this value was increased in steps of 0.5 mV in subsequent simulations. The deterministic component with normal dynamics was obtained from averaging 100 responses of a tangential cell to band-limited white-noise velocity fluctuations (the same as used for Fig. 6). Faster dynamics were obtained by compressing the time scale of the deterministic membrane potential component by a factor of 2 (fast dynamics) or by a factor of 4 (very fast dynamics). Therefore, the duration of the membrane potential fluctuations that were fed into the model and the corresponding sequences of spike trains were reduced from 2960 msec (normal dynamics) to either 1480 msec (fast dynamics) or 740 msec (very fast dynamics). The parameters of the stochastic component were fitted to the experimental data. Data evaluation and conventions as described in the legend of Figure 6. For the dynamical membrane potential fluctuations, the mean spike count and the spike count variance were determined across 500 individual response traces for each condition, for the constant membrane potential; 200 response traces were taken. A, Dependence of the spike count on the deterministic component of the membrane potential. B, Spike count variance as a function of the mean spike count within 20 msec time windows. C, Spike count variance as a function of the mean spike count within 100 msec time windows.

The across-trial variance of the simulated spike count was evaluated as described for the experimental data. The time-dependentvariance fluctuates in accordance with the experimental data (datanot shown). Analyzing the dependence of the variance on the meanspike count reveals that the variance is low for small spike countsand highest for intermediate activities. The variance is alwayssmaller than the mean spike count apart from the lowest activityclass (Fig. 6B). Note that the variance already starts to decreasewith increasing activity at ~2 spikes/20 msec time window (i.e.,100 spikes/sec), when the mean spike count still steeply increaseswith increasing depolarization. As is the case for the H1 cell,the initial increase in the variance is considerably more pronouncedwhen the spike count variance is evaluated within 20 msec thanwithin 100 msec time windows (Fig. 6, compare B, C). Interestingly,the spike count variance is not identical for the three inputsof different amplitude, although the properties of the membranepotential noise were identical. This is particularly obvious forthe 100 msec time window (Fig. 6C). The largest membrane potentialfluctuations are associated with the smallest spike count variance.Thus, at least for the large time window, the spike count variancediffers for the three different input signals, although the membranepotential noise has not changed. These model simulations withphysiologically plausible parameters allow us to conclude thatthe spike count variance is affected, at least to a small extent,by the overall amplitude of the deterministic, stimulus-inducedinput. Therefore, it is not possible to infer, without furtherevidence, changes in the stochastic component of the membranepotential from changes in the spike count variance. Merely changingthe amplitude of the deterministic membrane potential fluctuationsand leaving the stochastic membrane potential fluctuations unalteredmay suffice to explain the slight dependence of the spike countvariance on stimulus size (Fig. 1C,D).

Variation of the time course of the deterministic membrane potential component
To test whether the dynamics of the deterministic membrane potential component affects the variability of the spike output,input signals that differed with respect to their dynamical propertieswere used as input to the model of spike generation: (1) constant,(2) fluctuating according to the experimental results, or fluctuating(3) twice ("fast membrane potential dynamics") or (4) four timesas fast ("very fast membrane potential dynamics"). The lattertwo stimuli were obtained by compressing the time scale of thesignal without changing its amplitude. The dynamics of the membranepotential input does not much affect the spike count variancedetermined in 20 msec time windows as long as the membrane potentialfluctuations are not faster than those elicited by white-noisevelocity stimulation (Fig. 7B). Even constant membrane potentialslead to very similar spike count variances as membrane potentialfluctuations with dynamics as found when the cell is stimulatedwith white-noise velocity fluctuations. Only when the membranepotential fluctuates at least two to four times as fast as hasbeen elicited in motion-sensitive neurons by white-noise velocityfluctuations, the spike count variance decreases to some extent(Fig. 7B). The spike count variance evaluated within 100 msectime windows does not consistently depend on the membrane potentialdynamics (Fig. 7C). This inconsistency might be caused by smoothingout the very fast fluctuations by such relatively large time windows.Neither the variation of the amplitude (Fig. 6) nor the variationof the dynamical properties of the mean membrane potential (Fig.7) yielded changes of the corresponding spike count variancesthat are comparable with the experimentally determined ones whenpattern contrast was altered (Figs. 2C,D ,4C,D).

Variation of the properties of the membrane potential noise
So far, all model simulations were obtained by altering the deterministic membrane potential component without modifying theproperties of the membrane potential noise. In the following,the properties of the noise are altered while the deterministiccomponent remains unchanged. For the simulations shown in Figure8, the noise amplitude was either kept as experimentally derivedor it was scaled by a factor of 0.5 or 1.5. For the simulationsshown in Figure 9, the noise dynamics was altered by compressing("fast stochastic component") or dilating ("slow stochastic component")the time scale of the experimentally determined noise signalsby a factor of 2 but leaves the amplitude constant. When the propertiesof the membrane potential noise are altered, the mean spike countassociated with a given mean membrane potential as well as thespike count variance are affected (Figs. 8,9). The mean spikecount corresponding to a given mean membrane potential increaseswith increasing the amplitude of the noise (Fig. 8A). Similarly,larger spike counts are obtained for fast than for slowly varyingnoise (Fig. 9A). Independent of the time window used for the evaluationof the spike count variance, the spike count variance increasesconsiderably with the amplitude of the membrane potential noise(Fig. 8B,C) or when the noise fluctuates only slowly (Fig. 9B,C).When the membrane potential noise fluctuates faster than has beendetermined experimentally, the spike count variance decreasesslightly. One reason for the increased variability of spike responsesfor slow stochastic fluctuations may be the following. Under thiscondition, the spike count in an arbitrary time window can berather large because the noise lifts the membrane potential beyondthe threshold for a relative long time interval, or it can, forthe same time window, be rather low because the noise hyperpolarizesthe cell. As a consequence, the spike count variance across trialswill be large. In contrast, when the noise fluctuates more rapidly,the intervals with high and low activity attributable to noisealternate more rapidly so that the spike count stays statisticallyat more intermediate values. This leads to a relatively smallacross-trial variance. The changes obtained in the spike countvariance when the properties of the membrane potential noise arealtered may well account for the experimental results obtainedfor different pattern contrasts. This finding suggests that thestochastic membrane potential fluctuations that are the basisfor the variability in the spike count of the fly H1 cell cannotbe regarded to add linearly to the deterministic, stimulus-inducedcomponent of the membrane potential. Instead, it is suggestedthat the stochastic component decreases in amplitude or speedsup with increasing pattern contrast, inducing a smaller variabilityof the spike responses.

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Figure 8. Dependence of the responses of a simulated spiking neuron on the amplitude of the stochastic component of the membrane potential. The stochastic component scaled by a factor of 1 was derived from experimental data. To investigate the influence of the amplitude of the stochastic membrane potential component, it was increased or decreased by 50% (see insets). The deterministic component was obtained from a tangential cell during stimulation with band-limited white-noise velocity fluctuations (the same as used for Fig. 6). Data evaluation and conventions are as described in the legend of Figure 6. A, Dependence of the spike count on the deterministic component of the membrane potential. B, Spike count variance as a function of the mean spike count within 20 msec time windows. C, Spike count variance as a function of the mean spike count within 100 msec time windows.

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Figure 9. Dependence of the responses of a simulated spiking neuron on the dynamics of the stochastic component of the membrane potential. The stochastic component with normal dynamics was fitted to experimental data. Faster or slower dynamics of the stochastic membrane potential component were obtained by compressing (fast dynamics) or dilating (slow dynamics) the time scale of the stochastic component by a factor of 2. The deterministic component of the membrane potential was obtained from averaging 100 responses of a tangential cell to band-limited white-noise velocity fluctuations (the same as used for Fig. 6). It lasted for 2960 msec. Data evaluation and conventions are as described in the legend of Figure 6. A, Dependence of the spike count on the deterministic component of the membrane potential. B, Spike count variance as a function of the mean spike count within 20 msec time windows. C, Spike count variance as a function of the mean spike count within 100 msec time windows.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

We investigated how the spike count variance of the H1 neuron, a motion-sensitive TC in the fly visual system, depends onthe stimulus conditions. The following conclusions can be drawn.(1) The spike count variance is much smaller than the mean spikecount and does not depend much on the mean activity apart fromvery low activities. (2) The spike count variance is not determinedunambiguously by the activity level of the H1 neuron but is alsoaffected by the nature of the stimulus, although differently bydifferent stimulus parameters. Whereas the variance lies in thesame range for constant and dynamic stimuli and is not much affectedby changes in stimulus size, it increases considerably with decreasingpattern contrast. In accordance with our experimental results,the spike count variance of simulated spike trains does not changemuch with increasing mean spike activity and is much smaller thanthe mean spike count apart from the low-activity range. The variancemay even decrease in an activity range in which refractorinessdoes not yet lead to saturation of the mean spike count. Whereasin the model the spike count variance only slightly depends onthe dynamics and amplitude of the deterministic membrane potentialfluctuations, the membrane potential noise affects the variancemorestrongly.

Relationship between membrane potential fluctuations and spike count variance

Our model simulations revealed that there is no unambiguous relationship between a given membrane potential noise and theresulting spike count variance. When the deterministic membranepotential fluctuations onto which the noise superimposes get larger,the spike count variance slightly decreases. A similar dependencewas obtained experimentally when pattern size was increased. Therefore,this model result suggests that the membrane potential noise israther independent of pattern size. Because TCs pool with theirdendrite, the outputs of many retinotopically arranged elements(for review, see Egelhaaf and Borst, 1993a; Egelhaaf and Warzecha,1999), this conclusion indicates that the number of input elementsactivated by motion stimulation does not markedly influence theamplitude of the membrane potential noise in TCs. The decreasein spike count variance found for an increasing pattern contrastis too pronounced to be explained by the change in amplitude ofthe deterministic component with pattern contrast. Rather, ourmodel simulations suggest that the membrane potential noise eitherincreases in amplitude or slows down with decreasing patterncontrast.

In addition to the amplitude of the deterministic membrane potential component, also its dynamics was found in the model toaffect the spike count variance. When the membrane potential transientsget faster, the spike count variance slightly decreases. Thismodeling result should not be confounded with an earlier claim(de Ruyter van Steveninck et al., 1997) that constant stimulilead to variances of H1 cell responses in the range of the meanspike count. In contrast, we found for the H1 neuron that thespike count variances elicited by dynamical and by constant stimuliare much smaller than the mean spike count, apart from low spikeactivities (Warzecha and Egelhaaf, 1999). It should be noted thatthe variance of model cell responses is reduced only slightlyby changes in the dynamics of the deterministic membrane potentialfluctuations and only if these are much more transient than thosethat are elicited by white-noise velocity fluctuations as usedin the experimental analyses. Hence, the model results are inaccordance with our experimental data but in contrast to the conclusiondrawn by de Ruyter van Steveninck et al. (1997) (for a detaileddiscussion of the discrepancies between the studies, see Warzechaand Egelhaaf, 1999). In a recent study, de Ruyter van Stevenincket al. (2000) show responses of an H1 neuron with variances elicitedby constant velocity motion that are much smaller than the meanspike count, apart from low spike activities. This finding isin accordance with our data. Nonetheless, in the example shownby de Ruyter van Steveninck et al. (2000), the variance obtainedwith dynamical stimuli is smaller than that for constant stimuli,a finding which they interpret to support their earlier conclusions.It should be noted, however, that de Ruyter van Steveninck etal. (1997, 2000) argue on the basis of only a single example.Both their variances of responses to constant and dynamical stimuliare in the range of what we obtained in individual flies. In oursample of data, there are individual flies with response variancesinduced by constant velocity stimuli that are larger than thoseelicited by dynamical stimuli and vice versa. On average, varianceslie in the same range for both stimulus dynamics (Fig. 5). Giventhe great interindividual variability of the H1 cell responses,no sound quantitative conclusions can be drawn on the basis ofdata obtained on singleexamples.

Comparison with other cell types

In cortical neurons, the spike count variance is usually found to be in the range of the mean spike count (see introductoryremarks). Similar to the fly H1 neuron, the variance of retinalganglion cells has been reported to be much smaller (Berry etal., 1997). However, there are some discrepancies with respectto the dependence of the response variability of retinal ganglioncells on the activity level and the visual stimuli. In part ofthe studies, it has been concluded that the spike count varianceincreases with the mean spike count with approximately a powerlaw relationship (Levine et al., 1988, 1992). In other studies,the response variability was found to be essentially independentof the stimulus and the activity level of the cell (Dijk and Ringo,1987; Troy and Robson, 1992; Croner et al., 1993).

The differences in spike count variance in cortical neurons on the one hand, and in retinal ganglion cells and fly TCs onthe other hand, might be attributable to different statisticalproperties of the membrane potential noise. In our model simulations,the membrane potential noise had a gaussian probability distributionthat fitted our experimental results fairly well (Hengstenberg,1982; Haag and Borst, 1997), although the experimentally determineddistributions often slightly deviate in a characteristic mannerfrom a gaussian distribution. In cortical visual interneurons,the membrane potential fluctuations may deviate considerably froma gaussian distribution (Ferster and Carandini, 1996; Azouz andGray, 1999). The different statistics of membrane potential fluctuationsin fly TCs and retinal ganglion cells compared with cortical neuronsmight be attributable to a different input organization. WhereasTCs as well as retinal ganglion cells receive their major synapticinput from neurons originating from more peripheral processingstages, cortical neurons receive most of their input from feedbackconnections originating from higher processing stages (Barberiniet al., 2000).

Sources of response variability

Whereas the deterministic component of the membrane potential results from the processing of the changes in light intensityelicited during visual motion, the origin of the stochastic responsecomponent is not as clear. The reliability of TCs has been proposedto be limited by photoreceptor noise (de Ruyter van Steveninck,1986; Bialek et al., 1991). Although this possibility may applyto low light levels, under photopic conditions the synapses betweenphotoreceptors and first-order interneurons contribute considerablyto the membrane potential noise of the latter type of cells (Laughlinet al., 1987; Juusola et al., 1994, 1995, 1996). The noise levelin neurons of the peripheral visual system depends on the temporalproperties and the luminance of the stimulus (for review, seeLaughlin, 1989; Juusola et al., 1996). It cannot easily be predictedhow these findings relate to the response variability of the TCs.Between the first-order visual interneurons and the TCs, severalneurons are interposed (for review, see Hausen and Egelhaaf, 1989;Strausfeld, 1989). Therefore, additional noise is most likelyintroduced into the system at these processing stages. Irrespectiveof the precise origin of the membrane potential noise, it is clearfrom the highly synchronized spike activity of TCs with primarilyoverlapping receptive fields (Warzecha et al., 1998) that mostof the noise is generated peripherally to them. Only a minor partof it is attributable to their input synapses and to ion channelnoise at the level of the motion-sensitive cells themselves (Kretzberget al., 2000).

It may surprise that the spike count variance does not increase with pattern size and thus with the number of activated inputchannels. It seems most likely that also those elements that arenot activated by the motion stimulus contribute considerably tothe overall variability. In fact, even without motion stimulation,the noise level in TCs was found to increase with increasing luminance(Hengstenberg, 1982; Warzecha, 1994).

In summary, the membrane potential noise, as it manifests itself at the level of the TCs, cannot be regarded as a random,stimulus-independent variable that linearly adds to the deterministiccomponent of the membrane potential. Rather, the properties ofthe noise appear to change with pattern contrast. Because in almostall natural habitats the contrast varies across the retinal images,this result has important functional implications. Moreover, dataevaluation procedures that rely on additive gaussian noise needto be tested carefully for theirapplicability.

  FOOTNOTES

Received May 17, 2000; revised Sept. 7, 2000; accepted Sept. 11, 2000.

This study was supported by the Deutsche Forschungsgemeinschaft and the Studienstiftung des Deutschen Volkes. We thank JudithEikermann for help with the electrophysiological experiments.We are grateful to Katja Karmeier, Roland Kern, Holger Krapp,and Rafael Kurtz for reading this manuscript and helpfuldiscussions.
Correspondence should be addressed to Dr. Anne-Kathrin Warzecha, Lehrstuhl für Neurobiologie, Fakultät für Biologie, UniversitätBielefeld, Postfach 10 01 31, D-33501 Bielefeld, Germany. E-mail:ak.warzecha{at}biologie.uni-bielefeld.de.

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DISCUSSION
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