Effects of Activation of the Histaminergic Tuberomammillary Nucleus on Visual Responses of Neurons in the Dorsal Lateral Geniculate Nucleus

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The Journal of Neuroscience, February 1, 2002, 22(3):1098-1107

Effects of Activation of the Histaminergic Tuberomammillary Nucleus on Visual Responses of Neurons in the Dorsal Lateral Geniculate Nucleus
Daniel J. Uhlrich, Karen A. Manning, and Jin-Tang Xue
Department of Anatomy, University of Wisconsin Medical School, Madison, Wisconsin 53706

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

We investigated the effects of the central histaminergic system on afferent sensory signals in the retinogeniculocorticalpathway in the intact brain. Extracellular physiological recordingsin vivo were obtained from neurons in the cat dorsal lateral geniculatenucleus (LGN) in conjunction with electrical activation of thehistamine-containing cells in the tuberomammillary nucleus ofthe hypothalamus. Tuberomammillary activation resulted in a rapidand significant increase in the amplitude of baseline activityand visual responses in LGN neurons. Geniculate X- and Y-cellswere affected similarly. LGN cells that exhibited a burst patternof activity in the control condition switched to a tonic firingpattern during tuberomammillary activation. Effects on visualresponse properties were assessed using drifting sinusoidal gratingsof varied spatial frequency. The resultant spatial tuning curveswere elevated by tuberomammillary activation, but there was nochange in tuning curve shape. Rather, the effect was proportionateto the control response, with the greatest tuberomammillary effectsat spatial frequencies already optimal for the cell. Tuberomammillaryactivation caused a small phase lag in the visual response thatwas similar at all spatial frequencies, consistent with the inducedshift from burst to tonic firing mode. These results indicatea significant histaminergic effect on LGN thalamocortical cells,with no clear effect on thalamic inhibitory neurons. The histaminergicsystem appears to strengthen central transmission of afferentinformation, intensifying but not transforming the retinally derivedsignals. Promoting sensory input may be one way in which the histaminergicsystem plays a role inarousal.

Key words: histamine; lateral geniculate nucleus; tuberomammillary nucleus; visual receptive field; hypothalamus; burst and tonic modes; arousal; spatial tuning

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The dorsal lateral geniculate nucleus (LGN) of the thalamus conveys information from retinal ganglion cells to cortex alongthe primary visual perceptual pathway, and during this process,modification of visual signals can occur. Signal modulation isenabled within the LGN through a variety of extraretinal sourcesthat comprise the majority of the axonal projections to the LGN(Uhlrich and Cucchiaro, 1992; Van Horn et al., 2000; Sherman andGuillery, 2001). Many of the extrinsic projections modulate intrinsicmembrane properties of LGN cells through metabotropic receptorsto control neural response as a function of physiological or behavioralstate (Singer, 1977; Sherman and Koch, 1986; McCormick, 1992;Sherman and Guillery, 2001). Much attention has been directedtoward the cholinergic system, but aminergic systems also innervateLGN with pronounced physiological effects on LGN cells (McCormick,1992).

Least well studied of the aminergic group is the histaminergic system, which arises solely from neurons in the tuberomammillarynucleus in the hypothalamus (Panula et al., 1984, 1989; Uhlrichet al., 1993). This evolutionarily well preserved system projectswidely in the brain, including to LGN (Watanabe et al., 1984;Panula et al., 1989; Schwartz et al., 1991; Uhlrich et al., 1993;Manning et al., 1996). Receptor binding studies in LGN reveala high density of postsynaptic histamine H1 and H2 receptors andpresynaptic H3 receptors (Bouthenet et al., 1988; Ruat et al.,1990; Chazot et al., 2001). The histaminergic system is thoughtto play a primary role in enacting arousal in the brain, withtuberomammillary neurons active during the waking state and quiescentduring sleep (Vanni-Mercier et al., 1984; Lin et al., 1988; Sakaiet al., 1990; Monti, 1993; Brown et al., 2001). Application ofhistamine in vitro changes the firing pattern of LGN neurons fromthe burst mode of firing to the tonic mode (McCormick and Williamson,1991; McCormick, 1992), mimicking the change in general firingactivity recorded in the thalamus as the brain transitions fromsleep to waking (Steriade and Deschênes, 1984; Steriade and Llinás,1988).

The previous work suggests that the histaminergic system is capable of modulating neural responses in visual thalamus. Thecapacity to influence incoming sensory signals would seem idealfor histamine, given its reputed role in arousal. However, thenature of this influence is unclear, and extrapolation from invitro data involving other neuromodulators is problematic. Forexample, application of serotonin in vitro has a small depolarizingeffect on LGN cells (McCormick and Pape, 1990), but activationof the serotonergic dorsal raphe nucleus or application of serotoninin vivo usually produces a pronounced inhibition of LGN cells(Funke and Eysel, 1995). In addition, activation of the cholinergicsystem changes the receptive field tuning of LGN neurons in waysnot predicted by the cholinergic in vitro results (Sillito etal., 1983; Uhlrich et al., 1995). No previous work has examinedhistaminergic effects on neural responses to visual stimuli. Toaddress this, we used electrical activation of the tuberomammillarynucleus to determine the effects of histaminergic activation onvisual receptive field response properties inLGN.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Subjects in these acute recording experiments were five normal adult male and female cats obtained from a licensed supplier(Harlan Sprague Dawley, Indianapolis, IN). All procedures wereapproved by the University of Wisconsin-Madison Animal Care andUse Committee and met the guidelines of the National Institutesof Health detailed in the Guide for the Care and Use of LaboratoryAnimals.

Surgical procedure. Animals were anesthetized initially with gaseous halothane delivered via a nose cone, to effect, or injectionof ketamine (11 mg/kg, i.m.) plus xylazine (1-2 mg/kg, i.m.).The animal was then cannulated, intubated, placed in a stereotaxicapparatus, and maintained deeply anesthetized, to effect, with1-2% halothane in a 1:1 mixture of N₂O and O₂ throughout all surgicalprocedures. Paralysis was initiated with 5 mg of gallamine triethiodide,and the subject was artificially respirated. End-tidal CO₂ wasmaintained at 4 ± 0.2%, and body temperature was maintained at38°C via a feedback-controlled heating blanket. Heart rate andcortical electroencephalogram (EEG) were recorded continuouslyto monitor the state and well-being of theanimal.

The skull was surgically prepared for craniotomies to enable passage of stimulating and recording electrodes into the brain.EEG electrodes were fine stainless steel screws secured in theskull over frontal cortex. Wound margins and pressure points wereinfused with 2% lidocaine. Ophthalmic atropine sulfate and phenylephrinehydrochloride were applied to dilate the pupils and retract thenictitating membranes. The corneas were covered with contact lenseschosen by slit retinoscopy to focus the retinas on a cathode raytube 57 cm in front of theeyes.

During physiological recording, halothane was reduced to 0.4-0.8%, and paralysis was continued with an intravenous infusionof gallamine triethiodide (5 mg · kg¹ · hr¹) and D-turbocurarine (0.35 mg · kg¹ · hr¹). EEG and heart rate measures were monitored continuously toensure adequate levels ofanesthesia.

At the end of the acute recording experiment, the animal was given an intravenous overdose of pentobarbital sodium and perfusedthrough the heart with aldehyde fixatives. The brain was latersectioned to verify stimulation and recording sites in the hypothalamusand LGN,respectively.

Electrical stimulation. One pair of bipolar stimulating electrodes was placed across the optic chiasm at anterior 14 (A14)and lateral 1.0 (L1.0)-L1.5. Electrode depth was determined bymaximizing the visually evoked potential recorded through theelectrodes, and then they were cemented intoplace.

To stimulate the tuberomammillary region of the hypothalamus, a pair of electrodes was placed stereotaxically at L0.5 andheight $-$ 3.0 (H $-$ 3.0) and L3.0 and H $-$ 2.25, respectively, from A9.5to A10.0. We aimed for the region of the hypothalamus with thedensest distribution of histaminergic cells as identified by Uhlrichet al. (1993). Care was taken not to place the electrodes toofar laterally or rostrally where they might activate optic tractaxons, and none of the effects reported here could be replicatedby stimulation of optic chiasm electrodes. In all cases, electrodeplacement was confirmed histologically. Figure 1 illustrates thelocation of tuberomammillary nucleus-stimulating electrodes. Weactivated the tuberomammillary nucleus electrically by means ofpositive current pulses (50-100 µsec duration, 100-600 µA amplitude).Pulses were delivered in trains at 10-40 Hz for 500-2000 msec.

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Figure 1. Camera lucida reconstruction of a representative stimulation site in the tuberomammillary nucleus of the hypothalamus in coronal section at anterior 9.5. Solid shading, Electrode tracks; variable shading at bottom of the lateral track, location of the track at its full depth in an adjacent section; gray area, region of histaminergic cells in the tuberomammillary nucleus. cp, Cerebral peduncle; f, fornix; HLA, lateral hypothalamic area; HPA, posterior hypothalamic area; mtt, mammilothalamic and mammillotegmental tracts; ot, optic tract; V, third ventricle.

Cell classification. Glass pipettes were filled with 3 M KCl and beveled to a final impedance (at 100 Hz) of 5-15 m $Omega$ to recordcells in the A laminas of the LGN. The receptive field of eachisolated cell was plotted on a tangent screen, and the cell wascharacterized as an X- or Y-cell using a battery of tests (Sherman,1985). These included latency to optic chiasm stimulation, linearityof summation to a counterphase-modulated grating stimulus, receptivefield center size, response to large, fast-moving disks, phasicor tonic response to standing contrast, and receptive field sign(on and off center). All cells studied exhibited brisk responses.We encountered no cells with "lagged" characteristics (cf. Mastronarde,1987).

Visual stimulation. The visual stimuli were generated on the screen of a cathode ray tube that was driven by a computer-controlledfunction generator (Picasso). Gratings were the primary visualstimuli, but spots of light were also used. The contrast of thegratings was 60% as defined by (L_max $-$ L_min)/(L_max + L_min), whereL_max is maximum luminance, and L_min is minimum luminance. Space-averagedluminance was 40 cd/m². Gratings were counterphase-modulated to determine response linearityand were drifted horizontally, primarily at 4 Hz, to obtain spatialtuning curves based on responses to a range of 5-10 differentspatialfrequencies.

All cells were also tested in the baseline condition in which the visual stimulus was an unpatterned (contrast = 0 cycles/°),unchanging homogeneous field of the same space-averaged luminance.In the full-field condition, the field was unpatterned, and luminancewas varied temporally in a sinusoidal manner, typically at 4 Hz,between the high and low luminance values used in the gratingstimulus, L_max and L_min.

Experimental procedure. In initial experiments, we varied trial time parameters and quickly observed that maximal impact occurredduring the period of tuberomammillary stimulation. The characterof the effect did not change with longer duration stimulation,and the effect declined immediately thereafter. Thus, we adoptedtrial parameters that allowed us to focus on the most robust andconsistent part of the tuberomammillary effect. A typical trialof recording from an LGN neuron consisted of three parts: (1)a 1 sec control period; (2) a 0.5-2.0 sec period of tuberomammillarystimulation; and (3) a 1.0-3.0 sec period after termination oftuberomammillary stimulation to observe recovery of the response.During rare occasions in which the effect continued beyond 3 sec,the period of recording was extended, but these never revealedanything more than a continued return to baseline. In all cases,there was a 5-30 sec pause between individual trials to allowthe tuberomammillary effect todissipate.

Neurons were tested with the same visual stimulus present during all three parts of a trial. The spatial and temporal aspectsof the visual stimulus were varied from trial to trial. Thus,we obtained measures of spontaneous activity in the baseline conditionand recorded the responses to visual stimulation in which a gratingof selected spatial and temporal frequency drifted across thereceptive field of a cell before, during, and after tuberomammillarystimulation during eachtrial.

Spike data were conveyed to the computer for storage during the intertrial pause, and a new spatial or temporal frequencyfor the visual stimulus was selected, depending on the experimentalparadigm. Frequency was chosen in a block random style such thatfrequencies were chosen randomly without replacement until allfrequencies in the set were used. Then the procedure was repeated.The data presented here are from cells in which each data pointor histogram was the product of 4-15 trials typically containingfour temporal cycles per trial in the control condition and fourto six cycles per trial in the stimulationcondition.

Action potentials from recorded cells were fed through a window discriminator into the computer, where histograms synchronizedto the temporal visual stimulus cycle were generated and storedfor both on- and off-line analysis. Data from each visual stimulusdelivered at a particular spatial and temporal frequency for agiven cell were pooled, and histograms were generated. These datawere Fourier-analyzed to obtain measures of the overall averagefiring rate (F0) for each spatial frequency amplitude and phaseof the modulated response at the fundamental temporal frequency(F1) and its second harmonic (F2). F1 values were plotted as afunction of spatial frequency to generate the spatial tuning curveof the cell. The points on the tuning curves were then approximatedby functions representing the difference of two Gaussian functions,which represent responses from the center and surround of thereceptive field (Rodieck, 1965; Linsenmeier et al., 1982; Shapleyand Lennie, 1985).

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Effect of tuberomammillary activation on baseline activity: increases in responsivity

Extracellular recording data sets were collected from 33 visually responsive cells in the geniculate A laminas. We recordedbaseline physiological activity from cells when the visual stimuluswas an unmodulated homogeneous field of the same space-averagedluminance as the grating stimuli. Under these visual conditions,activation of the tuberomammillary nucleus of the hypothalamusresulted in an increase in firing rate in most LGN cells (86%of X-cells and 83% of Y-cells) over prestimulation control levels(Figs. 2, 3; see Figs. 6-8). The increase in baseline activity,quantified as F0, the average spike firing rate, during activationof the tuberomammillary nucleus was statistically significantfor both the X- and Y-cell populations (Wilcoxon signed rank test,X-cells, p = 0.0012; Y-cells, p = 0.0137). Although the increaseappeared greater for X-cells than Y-cells, the difference betweenX- and Y-cells was not statistically significant.

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Figure 2. Effect of tuberomammillary nucleus activation on spontaneous activity (A, B) and visual responses (C, D) of two representative LGN X-cells (A, C) and Y-cells (B, D). The visual stimulus in C and D, used most often in these experiments, was a sinusoidal grating drifting at 4 Hz. The bar below each histogram indicates the period of tuberomammillary (tm) stimulation.

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Figure 3. Comparison of the effect of tuberomammillary activation on the baseline response and the response to a grating stimulus in LGN X-cells (filled circles) and Y-cells (open circles). Each axis represents the change in the average number of spikes (F0) induced by tuberomammillary activation in the different conditions. The optimal grating spatial frequency, that which yielded the largest modulated response, was used for the visually driven response measure for each cell. An unmodulated homogeneous field was presented during the baseline condition.

The time course of the effect consisted generally of an immediate increase in baseline activity on onset of tuberomammillarystimulation, a maximal effect occurring during the period of tuberomammillarystimulation, and a more gradual return to prestimulation levelsafter stimulation terminated. In cells tested multiple times,including one cell seven times in conjunction with a variety ofvisual conditions, the pattern of results remained thesame.

The poststimulation effects varied across LGN cells. Most cells exhibited a simple return to their prestimulation activitylevel within 1-1.5 sec after termination of tuberomammillary stimulation(Fig. 2A). In contrast, the firing rate in two X-cells and twoY-cells remained elevated for 4 sec after stimulation (Fig. 2B).Finally, in a few X- and Y-cells, there was a temporary decreasein poststimulus firing rate in comparison with control levels(see Fig. 7A) or a change in firing pattern that included morebursts of action potentials (see Figs. 6, 7).

A subset of LGN cells appeared little affected by tuberomammillary activation (Fig. 3). Analysis of receptive field and otherresponse properties revealed no differences between affected andunaffected cells, which were encountered in the same electrodepenetrations.

Effect of tuberomammillary activation on responses to visual stimulation

Significant increases in visual responses
Figure 2, C and D, illustrates the responses of X- and Y-cells to visual stimuli presented before, during, and after a 1500msec period of tuberomammillary activation. A drifting sinusoidalgrating produced a modulation in physiological activity as thelight and dark bars of the grating passed across the receptivefield of the cell. Both cells in Figure 2, C and D, exhibitedan increase in the depth of the modulated response during tuberomammillaryactivation when compared with the prestimulation control condition.The depth of modulation was quantified as the amplitude of theFourier component of the response of a cell at the temporal driftrate of the grating (F1). The increase in the visually modulatedresponse with tuberomammillary activation was statistically significantfor X-cells (median F1 increase from 21.05 spikes/sec before stimulationto 32.15 spikes/sec during stimulation; Wilcoxon signed rank test,p = 0.004) and Y-cells (30.25 to 39.25 spikes/sec; Wilcoxon signedrank test, p = 0.0093).
The increase in visual response developed rapidly within the first visual stimulus cycle and persisted for the duration oftuberomammillary activation. Consistent with the poststimuluschanges in baseline activity, some cells exhibited a temporarychange in firing pattern during the period immediately after cessationof tuberomammillary stimulation (see Figs. 2D, 6, 7) during whichthe physiological response was narrower in width and of higherspike frequency. This pattern is consistent with change to theburst mode of response (seebelow).

Effect on baseline activity versus visually modulated activity
Figure 3 summarizes the baseline and visual effects of tuberomammillary activation in the same cells. Tuberomammillary activationproduced a consistent change in both baseline activity and visuallydriven activity for the majority of cells. There was a significantcorrelation between the effects on baseline and visually drivenactivity for X-cells (r = +0.5193; Spearman correlation coefficient,p = 0.0285) and for Y-cells (r = +0.4912; Spearman correlationcoefficient, p = 0.0524). The increase in response level of X-and Y-cells, as a whole, attributable to tuberomammillary stimulationappeared greater in the visual condition than in the baselinecondition, but this was not statistically significant, nor wasthere a significant difference between X- and Y-cells in the changein response in the baseline condition or in the visualcondition.

Effect of tuberomammillary activation on response mode: burst-to-tonic change

The state of LGN neurons varies between two well documented modes of response, the burst mode and the tonic mode (Jahnsenand Llinás, 1984; Steriade and McCarley, 1990; Sherman, 1996).Previous work has demonstrated that several neuromodulatory systemscan enable the change in firing mode in thalamic cells, actingthrough a low-threshold calcium conductance within the cell membrane(McCormick, 1992; Sherman, 1996). We now extend these findingsto the tuberomammillary system in vivo.

Tuberomammillary activation can switch an LGN neuron from the burst mode of firing to the tonic firing mode. The initial visualresponse of the cell seen in the raster plot in Figure 4A, tophalf, consisted of short, high-frequency (>250 Hz) bursts of 2-10action potentials, preceded by at least 100 msec of no activity.This pattern of response fits the extracellular criterion forburst firing defined by Lu et al. (1992) and Guido et al. (1992).The visual responses converted quickly to the tonic firing modewith tuberomammillary activation, exhibiting longer trains ofaction potentials firing at a markedly lower frequency.

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Figure 4. Raster plot and histograms of LGN cell mode change during tuberomammillary stimulation. A, The raster plot in the top half displays action potential activity of a Y-cell in response to a drifting grating stimulus during nine successive 2 sec trials from which the adjacent histogram was constructed. The horizontal bar indicates the period of tuberomammillary stimulation during which the cell switched from the burst-firing mode to the tonic mode. The sinusoid indicates the periodicity but not the absolute phase of the 4 Hz grating stimulus. A phase lag of 0.25 radians developed during the mode shift, corresponding to a response shift of 10 msec. B, Histograms obtained from the same Y-cell as in A in response to a spot of light slightly smaller (top histogram; n = 7 trials) and slightly larger (bottom histogram; n = 15 trials) than the receptive field center of the cell, which was 1.1° in diameter. The spot was flashed on and off at 1 Hz as indicated below each histogram. As in A, the transient burst responses of the cell became more tonic as a result of tuberomammillary (TM) stimulation.

The change in response mode was also evident in the resulting peristimulus time histogram (Figs. 4A, 5). Initially, the histogramcontained long pauses in the response of each cell, often punctuatedby brief periods of high firing rate that reflect the bursts.In contrast, the visual responses of the cell assumed a broaderand more sinusoidal shape during the period of tuberomammillaryactivation, more closely resembling the time course of the visualstimulus. F1 values increased and F2 values decreased during thisperiod, consistent with an increase in linearity of response duringtuberomammillary activation (Uhlrich et al., 1995). The mode changereverted promptly back to burst mode in some cells once tuberomammillarystimulation ceased, as shown in Figure 5A, and changed more slowlyin others, as seen in Figure 5B. The responses of a cell weresometimes more transient than apparent in the histogram becauseof variation in the latency of the burst responses. This is illustratedin the clearly transient raster responses in Figure 4A, left half.Those in the first visual cycle of the trial vary in latency andyield a broader averaged response than those of the second visualcycle of more constant latency.

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Figure 5. Change in response mode in two representative geniculate Y-cells during tuberomammillary activation. Horizontal bars in this and subsequent figures indicate the period of tuberomammillary (tm) stimulation. A grating visual stimulus drifted at 4 and 2 Hz in A and B, respectively. Tuberomammillary activation produced a phase lag of 0.65 radians, corresponding to a response shift of 26 msec for the cell in A, and a phase lag of 0.67 radians, corresponding to a response shift of 53 msec for the cell in B.

By virtue of shifting from the burst to tonic firing mode, the histogram shape changed, and the weight of the response shiftedlater in time. The sinusoidal waveform showing the drift frequencyof the grating stimulus is indicated below the histogram in Figure4A. When the waveform is centered on the three cycles of tonicresponse on the right side, it is evident that the weight of theburst responses on the left occurs slightly earlier in the stimuluscycle.

The burst-to-tonic change in the visual response with tuberomammillary stimulation was not dependent on the presence of gratingstimuli. The transformation was similar when the visual stimuluswas a spot of light on the receptive field of the cell (Fig. 4B).

Most cells we recorded were in the tonic mode of firing before onset of tuberomammillary stimulation, presumably reflectingthe low level of anesthesia used during the recording phase ofthese experiments. Cells initially in the tonic mode stayed inthe tonic mode during stimulation and never reverted back to theburst mode after stimulation. These findings are consistent within vitro histamine studies on LGN cells (McCormick and Williamson,1991). A switch to or an enhancement of the burst mode patternof firing was observed in a few cells only during the brief periodafter termination of the tuberomammillary stimulation (Figs. 6,7).

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Figure 6. Responses of an LGN X-cell to a set of visual stimuli before, during, and after tuberomammillary (tm) stimulation. From top to bottom, the histograms show responses during baseline activity and to the modulated full-field (FF) and grating stimuli of 0.25, 0.75, and 1.25 cycles/° delivered at 4 Hz. The cell was tested with a total of eight grating stimuli of varied spatial frequency.

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Figure 7. Responses of an LGN Y-cell to a set of visual stimuli. The cell was tested with a total of seven grating stimuli of varied spatial frequency in addition to the full-field (FF) and baseline conditions. Conventions are as in Figure 6.

Effect of tuberomammillary activation on spatial tuning

The visual responses of individual LGN cells to grating stimuli were recorded across a range of spatial frequency values inconjunction with tuberomammillary activation, and examples ofresults for two representative cells are illustrated in Figures6 and 7. In both cases, tuberomammillary activation resulted inan increase in the visual response at all spatial frequencies.These effects held for cells whose responses were primarily tonicunder both control and tuberomammillary conditions (Fig. 6) aswell as for cells whose firing mode was changed from burst totonic by tuberomammillary activation (Fig. 7).

It is evident from the sets of histograms in Figures 6 and 7 that both the amplitude of the visual response and the effectof tuberomammillary activation depend on the spatial frequencyof the grating visual stimulus. We quantified these effects byperforming a Fourier analysis of data such as those shown in Figures6 and 7. Data from 14 X-cells and 12 Y-cells from four cats wereincorporated into the analysis from which we derived measuresof F0 (average number of spikes) and F1 (depth of modulated responseat the temporal drift rate of the grating) for the control andtuberomammillary stimulation conditions at each spatial frequency.The F1 amplitudes from the complete data set of the cell depictedin Figure 7 and from three additional cells are plotted as a functionof spatial frequency of the grating stimulus in Figure 8, A, C,E, and G. The curves have the inverted U shape that has been reportedpreviously for LGN X- and Y-cells (So and Shapley, 1981), withY-cells showing less of a decline at low spatial frequencies anda lower spatial resolution than X-cells.

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Figure 8. Effects on spatial tuning of LGN Y-cells (A-D) and X-cells (E-H). A, C, E, G, Amplitude of visual response plotted as a function of spatial frequency of the 4 Hz grating visual stimulus for four geniculate cells. Measures of F1 amplitude were obtained before (ctrl, circles) and during (stim, squares) tuberomammillary (tm) activation. Solid curves drawn through the F1 data points represent best-fit difference-of-Gaussians functions for control (thin curves) and tuberomammillary stimulation (thick curves) conditions. The average number of spikes in the response (F0) obtained before (dotted curves) and during (dashed curves) stimulation is also shown. Key in G applies to A, C, E, and G. B, D, F, H, Stimulation-induced change in F1:F0 ratio as a function of stimulus spatial frequency for the four illustrated cells. B is derived from the data in A, D from C, F from E, and H from G. The value [(F1 stim/F0 stim) $-$ (F1 ctrl/F0 ctrl)]/(F1 ctrl/F0 ctrl) is plotted on the ordinate.

Analysis using difference of Gaussians model
The thick unbroken curves fit through the F1 data points in Figure 8 represent the best-fit curves obtained using the differenceof Gaussians model of center-surround receptive field organization(So and Shapley, 1981; Linsenmeier et al., 1982). The differenceof Gaussians fits provide measures of the amplitude and radiusof the receptive field center and receptive field surround fromeach spatial tuning curve. Although more complex receptive fieldmodels incorporate phase parameters (Kaplan, 1991), those modelswere not used, because tuberomammillary activation had littleeffect on the phase of the response (see below). We found expecteddifferences between X- and Y-cells per se in the difference ofGaussians values (cf. So and Shapley, 1981) but no differencebetween cell types in the effect of tuberomammillary activationon the difference of Gaussiansvalues.
For X- and Y-cells combined, tuberomammillary activation produced a significant increase in the amplitude of the receptivefield center (control, mean = 72.9; tuberomammillary stimulation,mean = 121.4; Wilcoxon signed rank test, p = 0.0005), reflectingan increase in the height of the spatial tuning curves. We alsofound a slight decrease in the radius of receptive field center(control, mean = 0.61°; tuberomammillary stimulation, mean = 0.55°;Wilcoxon signed rank test, p = 0.0075). Changes in the receptivefield surround amplitude and radius parameters were not significant.Finally, there was no significant change in the ratio of the strengthof the receptive field surround (proportional to the product ofthe amplitude of the surround and the square of its radius) tothe strength of the center (control, 0.66; tuberomammillary, 0.68;Wilcoxon signed rank test, not significant). The lack of changein the measure of surround strength relative to center strengthindicates that the increase in the height of the spatial tuningcurve with tuberomammillary activation was not accompanied bya significant change in tuning curve shape, because proportionateincreases at all spatial frequencies lead to a proportionate increasein the amplitude of center and surroundresponses.
The difference of Gaussians analysis suggests that the increase in firing rate during tuberomammillary activation was greatestat spatial frequencies that elicited the largest responses underthe control condition. This trend was confirmed and summarizedin Figure 9, which shows the change in modulated response, F1,as a function of the F1 response in the control condition. Datafrom 13 X- and Y-cells across the effective range of spatial frequenciesare plotted. The graph shows again that the general effect oftuberomammillary activation is to increase the visual responseof the cell. In addition, there is a significant correlation betweenthe size of the visual response in the control condition and themagnitude of the tuberomammillary effect (r = +0.2724; Spearmancorrelation coefficient, p = 0.0029). Thus, the greatest effectsof tuberomammillary activation are seen under conditions in whichthe cell already has a well developed visual response.

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Figure 9. Tuberomammillary-induced change in F1 values (F1_STIM $-$ F1_CTRL) plotted as a function of prestimulation F1 values (F1_CTRL). Pooled data from seven Y- and four X-cells tested across a range of gratings of varied spatial frequency presented at 4 Hz are shown.

Tuberomammillary enhancement of responses with high F1 content
Figure 8 also shows curves indicating the F0 values for each cell under the control and tuberomammillary stimulation conditions.Similar to the increase in F1 values, the F0 values increasedwith tuberomammillary activation. This was expected because inmost cases the visual response was rectified, and increases invisual response would be accompanied by an increase in the averagespike firing rate. However, there are cases in which the F0 increasewas proportionally greater than F1, primarily when the visualresponse was relatively low, such as with the lowest and highestspatial frequency stimuli (Fig. 8A,E). We quantified this observationby computing the F1:F0 ratio for the control and tuberomammillarystimulation conditions, and the difference in this ratio was plotted(Fig. 8B,D,F,G). A value of 0 indicated no difference in the ratio.Negative values occurred when tuberomammillary activation resultedin a proportionally greater increase in F0 than in F1. Note thata rectified response precluded positive values for which F1 increasedmore than F0. The F1:F0 ratio was generally well maintained undervisual conditions that elicited a large modulated response, andthe ratio declined at spatial frequencies that produced smallerresponses.
The relationship between the change in F1:F0 ratio and the size of the control F1 amplitude was highly significant (r = 0.6464;Spearman correlation coefficient, p < 0.0001). This result indicatesthat tuberomammillary stimulation differentially enhances signalswith high F1 content. This is consistent with our other findingthat tuberomammillary activation results in a greater increasein well modulated visual responses than in poorly modulated visualresponses.

Effects of tuberomammillary activation on phase

Tuberomammillary activation had a small effect on the phase of the visual responses of geniculate cells. When measured acrossresponses to all spatial frequencies, a phase lag was found forX-cells (average = 0.09 radians; Mann-Whitney U test, p = 0.043)and for Y-cells (0.08 radians; Mann-Whitney U test, p = 0.048).These phase lags were small for the population, correspondingto response shifts of <4 msec on average for gratings driftingat 4 Hz. The delayed visual response is consistent with, and moreoverexplained by, the shift in time to peak response that accompaniesthe burst-to-tonic mode change produced in LGN cells. When thereis a burst-to-tonic mode change, as is clearly evident in Figures4, 5, and 7, there is a visible delay in reaching the peak ofthe response as it transitions from a narrow, sharp burst to abroader shape, more sinusoidal in form. It was in these cellsthat the greatest phase lags occurred. For other geniculate cellswith less dramatic changes in histogram shape, a phase shift mayoccur if the proportion of burst firing in the response is reducedeven minimally. Regardless of whether this small shift representsa simple increase in latency or a true phase lag, both are consistentwith a delayed time to peak associated with a burst-to-tonic changein firing mode. Finally, there was no significant difference inphase effects between X- and Y-cells or between the size of theeffect for low spatial frequency visual stimuli compared withhigh spatial frequencystimuli.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Primary effects and mechanisms

We found that activation of the tuberomammillary nucleus can produce significant and straightforward effects on LGN neuronsin the intact brain. These effects include an increase in baselineneuronal activity and a change to the tonic mode of firing bycells whose firing pattern was previously in the burst mode. Wealso found that visual responses were enhanced by tuberomammillaryactivation. The excitatory effects occurred across the range ofvisual spatial frequencies to which the cell would respond butwere greatest at spatial frequencies that were already optimalfor the neuron. The spatial tuning curve of LGN cells was elevatedby tuberomammillary activation, but there was no significant changein tuning curveshape.

These results are consistent with the effects of histamine reported previously in vitro. Application of histamine in a slicepreparation produced a depolarization because of a decrease ina potassium conductance, I_{K leak}, and a depolarizing shift inthe activation curve of a hyperpolarization-activated cation conductance,I_h (McCormick and Williamson, 1991). Such depolarizing effectsare consistent with the significantly increased firing rates weobserved in vivo. LGN thalamocortical cells generally have a lowerfiring rate than their retinal ganglion cell inputs, reflectingtransmission failure at the retinogeniculate synapse (Clelandet al., 1971; Cleland and Lee, 1985; Mastronarde, 1987). The depolarizationresulting from histaminergic activation appears to act to restorethe efficiency of the retinal $right-arrow$ geniculate synapse, thereby improvingtransmission along the retinogeniculocorticalpathway.

The second major finding is that tuberomammillary activation can change the firing pattern of LGN neurons. When the responseof a cell initially consisted of short, high-frequency burstsof action potentials, tuberomammillary stimulation altered thefiring pattern to a longer, lower-frequency train of action potentials.The firing rate can be altered through many mechanisms, and itis likely that the aforementioned histamine-mediated decreasein potassium conductance and resulting increases in membrane resistanceand time constant contribute. The most likely reason for the changein firing pattern is the well documented change from burst totonic mode that thalamic neurons can undergo. The depolarizationthat accompanies histamine application inactivates a low-thresholdcalcium conductance, I_t (McCormick and Williamson, 1991). TheI_t current is the basis for the burst pattern of activity in thalamicneurons; its inactivation by depolarization elevated the LGN cellfrom the burst mode of firing to the tonic mode. This is consistentwith our in vivo observations of histamine activation switchingcells to, or maintaining cells in, the tonic firing mode. Althoughthe burst mode is characteristic of sleep, the tonic mode predominatesoverwhelmingly in the awake brain state and is associated withan enhancement of linear signal processing in LGN. Thus, histamineshifted the cell toward the tonic mode, the response mode thatmore faithfully transmits retinal signals to cerebral cortex (Sherman,1996).

The direct tuberomammillary-to-LGN anatomical connection (Uhlrich et al., 1993) and the similarity of our in vivo findingsto the in vitro results (McCormick and Williamson, 1991) suggestthat these effects occurred through the direct histaminergic pathway.Nevertheless, it remains possible that histaminergic pathwayscould also affect LGN neurons indirectly through other brain regionsthat project to LGN such as cortex. For example, the poststimulationresponse of the cell in Figure 7 was more transient than the controlresponse preceding stimulation. Such a result is not readily explainedby a direct depolarizing histaminergic effect and may insteadreflect indirect effects on LGN circuitry. It is not clear whatcombination of direct and indirect histaminergic effects contributedto the modified responses reported here, and further study isrequired to establish this. The present results demonstrate theimpact of the activated histaminergic system on the intact geniculatecircuitry.

No effect on inhibitory cells

An important finding is that histaminergic activation impacts most on visual responses at those spatial frequencies to whichan LGN cell already has a robust response, in essence producinga multiplicative effect on cell response. This translates intono significant change in the shape of the spatial tuning curveof a cell with tuberomammillary stimulation and, moreover, indicatesno change in the spatial receptive field organization of the cell.These findings suggest that the underlying histaminergic effectson thalamic neural circuitry reflect direct actions on thalamocorticalcells with little or no involvement of thalamic GABAergicneurons.

Retinal ganglion cells provide the primary visual drive to LGN cells, and LGN cell receptive fields reflect, in large part,their retinal input (Cleland and Lee, 1985; Sherman and Guillery,2001). It therefore follows that enhancing the response to retinalinput would result in an increase in firing rate without changein receptive field organization. Retinal ganglion cells have areceptive field center and surround; therefore, an enhancementof retinogeniculate drive should lead to an increase in the strengthof both. This, in fact, is the result weobserved.

Although LGN cells derive their primary receptive field features from retinal input, elaboration can occur in the form ofan enhanced receptive field surround. The additional surroundeffect is thought to arise from inhibitory inputs from GABAergicthalamic cells, in particular, from interneurons within the LGNand cells of the dorsally adjacent perigeniculate nucleus or thalamicreticular nucleus. Significant histaminergic effects on thalamicinhibitory cells would have altered the strength of the receptivefield surround of LGN cells relative to the center. However, thiswas not observed. Instead, the receptive field center and surroundwere affected proportionally, suggesting that histaminergic activationhad little or no effect on thalamic inhibitory neurons. This isconsistent with the in vitro report of no direct effect of histamineon LGN interneurons (Pape and McCormick, 1995) and stands in contrastto the significant tuning curve effects observed after cholinergicactivation of the LGN (Uhlrich et al., 1995).

Analysis of phase change in the visual responses in our data yields the same conclusion as that derived from the spatial tuningcurve data; they imply no additional impact on the geniculatecell receptive field surround from tuberomammillary activation.We found no difference in the size of the phase shift, a smallphase lag, at high versus low spatial frequencies. Because receptivefield center and surround mechanisms contribute differentiallyto responses at low and high spatial frequencies, an interactionbetween the effect on phase and spatial frequency would suggestdifferential effects on the geniculate receptive field surroundrelative to the center. However, this was not observed. Instead,the change in firing mode can account fully for the small phaselag observed across all spatialfrequencies.

Histaminergic activation in vivo

The histaminergic system is understood to act nonsynaptically (Takagi et al., 1986; Uhlrich et al., 1993; Brown et al., 2001),without need for histamine release sites and histamine receptorsto be apposed directly, and this likely explains the efficacyof the histaminergic effect in the LGN despite the presence ofonly moderately dense tuberomammillary axons (Uhlrich et al.,1993). Histamine also uses enzymatic catabolism instead of a fasthigh-affinity uptake mechanism. Histamine, in effect, seems toact as a local hormone, diffusely impacting cells (Wada et al.,1991a,b). Thus, a high density of histaminergic fibers is notrequired to produce significant histaminergic effects (Schwartzet al., 1991), particularly given the high density of histaminergicreceptors in the LGN (Bouthenet et al., 1988; Ruat et al., 1990)and the consistent depolarization in thalamocortical cells inthe LGN with histamine application in vitro (McCormick and Williamson,1991).

Given the density of histaminergic receptors in the LGN and the strong depolarizing effects of histamine application in vitro(McCormick and Williamson, 1991), it warrants comment that somecells in the present experiments showed little or no effect fromtuberomammillary activation. It is possible that these cells mighthave been LGN interneurons, which are not distinguishable fromthalamocortical cells in our extracellular recordings and arenot affected directly by histamine (Pape and McCormick, 1995).Although it is likely that most of our recordings were from thalamocorticalcells, given that they comprise ~75% of the neurons in the LGN(Sherman and Koch, 1986) and the electrode sampling biases favorencountering thalamocortical cells, a lack of histaminergic effectin some LGN cells would be consistent with recording from LGNinterneurons.

Another possibility is that some cells were unaffected because of the inability to activate the entire population of histaminergiccells in the hypothalamus. Stimulation electrodes could activateonly a portion of the tuberomammillary nucleus, the whole of whichis wide-ranging and irregularly shaped (Uhlrich et al., 1993)and for which there is no clear mapping of tuberomammillary neuronsonto brain target regions. Furthermore, we deliberately avoidedplacing stimulating electrodes in the lateral- and rostral-mostportions of the nucleus because of their proximity to the optictract. Thus, some LGN cells were likely unaffected because wedid not activate the entirety of the tuberomammillarynucleus.

Functional considerations

Tuberomammillary stimulation strengthened and produced higher-fidelity sensory signals in the retinogeniculocortical pathway.We found this in the ascending visual pathway, but histaminergicaxons are also present in other thalamic relay nuclei (Watanabeet al., 1984; Panula et al., 1989), and it is likely that histaminesimilarly affects other sensory modalities. Promoting transmissionof afferent signals centrally may be one way in which the histaminergicsystem contributes to arousal in the mammalianbrain.

The histaminergic system appears to use the same intrinsic membrane currents as the cholinergic and other aminergic systemsto directly depolarize LGN thalamocortical cells (McCormick andPape, 1990; McCormick and Williamson, 1991; McCormick, 1992; Zhuand Uhlrich, 1998). The other neuromodulatory systems additionallyappear to act directly on thalamic inhibitory neurons. The cholinergicsystem affects both thalamic reticular cells and intrinsic interneurons;the serotonergic and noradrenergic influence on LGN interneuronsis less clear, but they robustly affect thalamic reticular cells(Kayama et al., 1982; McCormick and Prince, 1988; McCormick andWang, 1991). These other systems may alter visual receptive fieldtuning through their actions on inhibitory neurons, as has beendemonstrated for the cholinergic system (Sillito et al., 1983;Uhlrich et al., 1995). The histaminergic system differs in producingmore pure enhancement of the retinally derived afferent signal,with little or no direct effect on inhibitory neurons, thus boostingbut not transforming visualsignals.

  FOOTNOTES

Received July 19, 2001; revised Sept. 27, 2001; accepted Nov. 9, 2001.

This work was supported by the National Institutes of Health National Eye Institute and the University of Wisconsin MedicalSchool under the Howard Hughes Medical Institute Research ResourcesProgram for MedicalSchools.
Correspondence should be addressed to Dr. Daniel Uhlrich, Department of Anatomy, University of Wisconsin Medical School, 1300University Avenue, Madison, WI 53706-1532. E-mail: duhlrich{at}facstaff.wisc.edu.

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