Modifications of Vestibular Responses of Individual Reticulospinal Neurons in Lamprey Caused by Unilateral Labyrinthectomy

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Modifications of Vestibular Responses of Individual Reticulospinal Neurons in Lamprey Caused by Unilateral Labyrinthectomy

T. G. Deliagina and E. L. Pavlova

The Nobel Institute for Neurophysiology, Department of Neuroscience, Karolinska Institute, SE-171 77 Stockholm, Sweden

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Deliagina, T. G. and E. L. Pavlova. Modifications of Vestibular Responses of Individual Reticulospinal Neurons in Lamprey Caused by Unilateral Labyrinthectomy. J. Neurophysiol. 87: 1-14, 2002. A postural control system in the lamprey is driven by vestibular input and maintains the dorsal-side-up orientation of theanimal during swimming. After a unilateral labyrinthectomy (UL),the lamprey continuously rolls toward the damaged side. Normally,a recovery of postural equilibrium ("vestibular compensation")takes about 1 mo. However, illumination of the eye contralateralto UL results in an immediate and reversible restoration of equilibrium.Here we used eye illumination as a tool to examine a functionalrecovery of the postural network. Important elements of this networkare the reticulospinal (RS) neurons, which are driven by vestibularinput and transmit commands for postural corrections to the spinalcord. In this study, we characterized modifications of the vestibularresponses in individual RS neurons caused by UL and the effectexerted on these responses by eye illumination. The activity ofRS neurons was recorded from their axons in the spinal cord bychronically implanted electrodes, and spikes in individual axonswere extracted from the population activity signals. The sameneurons were recorded both before and after UL. Vestibular stimulation(rotation in the roll plane through 360°) and eye illuminationwere performed in quiescent animals. It was found that the vestibularresponses on the UL-side changed only slightly, whereas the responseson the opposite side disappeared almost completely. This asymmetryin the bilateral activity of RS neurons is the most likely causefor the loss of equilibrium in UL animals. Illumination of theeye contralateral to UL resulted, first, in a restoration of vestibularresponses in the neurons inactivated by UL and in an appearanceof vestibular responses in some other neurons that did not respondto vestibular input before UL. These responses had directionalsensitivity and zones of spatial sensitivity similar to thoseobserved before UL. However, their magnitude was smaller thanbefore UL. Second, the eye illumination caused a reduction ofthe magnitude of vestibular responses on the UL side. These twofactors tend to restore symmetry in bilateral activity of RS neurons,which is the most likely cause for the recovery of equilibriumin the swimming UL lamprey. Results of this study are discussedin relation to the model of the roll control system proposed inour previous studies as well as in relation to the vestibularcompensation.

	INTRODUCTION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Ablation of one vestibular organ (unilateral labyrinthectomy, UL) evokes severe motor disorders in all classes of vertebrates.They include abnormal eye positions, spontaneous ocular nystagmus,asymmetry in the head and trunk posture, etc. Over time, thesedisorders gradually diminish. This process of the recovery ofmotor functions is usually referred to as "vestibular compensation"and is considered to be one of the most striking examples of CNSplasticity (for a review, see Dieringer 1995; Shaefer and Meyer1974; Smith and Curthoys 1989; Vidal et al. 1998). Despite extensivestudies of vestibular compensation, neuronal mechanisms of theorigin of different UL-evoked symptoms and of the recovery ofmotor functions are still badly understood. The main reason forthis is that the corresponding neuronal networks are extremelycomplex.

We have been investigating the effect of UL on postural stability, as well as the process of recovery of postural function,by using a simple biological model $---$ the lamprey, a lower vertebrate(cyclostome). A reason for this is that the basic design of thelamprey CNS, and especially of the brain stem and spinal cord,is similar to that of higher vertebrates (Nieuwenhuys et al. 1998),but the lamprey presents many more opportunities for analyticalstudies of the nervous mechanisms for postural control, includingstudies at the network and cellular levels (Macpherson et al.1997; Orlovsky 1992).

When swimming, the intact lamprey actively stabilizes the dorsal-side-up orientation of the body due to the activity of thepostural control system driven by vestibular input (de Burletand Versteegh 1930; Deliagina 1995, 1997a,b; Ullén et al. 1995a).Visual input plays only a modulatory role: a unilateral eye illuminationevokes a roll tilt toward the source of light-"the dorsal lightresponse" (Ullén et al. 1993, 1995b). Because the postural controlsystem in the lamprey is driven by vestibular input, the effectof UL in this animal is most dramatic. In the swimming lamprey,UL results in a complete loss of postural stability and in continuousrolling toward the damaged labyrinth (de Burlet and Versteegh1930; Deliagina 1995, 1997a). During a few weeks following UL,the animals gradually recover their capacity to maintain equilibrium(Deliagina 1995, 1997a). The equilibrium can be restored immediately,however, by illuminating the eye contralateral to UL or by electricallystimulating the corresponding optic nerve. The motor behaviorof the stimulated animals is not distinguishable from that ofwell compensated animals (Deliagina 1995, 1997b). This findingsuggests that functional changes in postural mechanisms in thestimulated and compensated animals may be similar. In the presentstudy, we examined these changes in the stimulated animals anddiscuss a possible relevance of our findings for vestibularcompensation.

The postural network in the lamprey has been characterized in considerable detail. Important elements of this network arethe reticulospinal (RS) neurons, which transmit commands for posturalcorrections from the brain stem to the spinal cord. The RS pathwaysoriginate from four reticular nuclei of the brain stem: the mesencephalicreticular nucleus (MRN) as well as the anterior (ARRN), middle(MRRN) and posterior (PRRN) rhombencephalic reticular nuclei (Nieuwenhuys1972). The RS neurons receive vestibular input through interneuronsof the vestibular nuclei (Koyama et al. 1989; Northcutt 1979;Rovainen 1979; Rubinson 1974; Stefanelli and Caravita 1970; Tretjakoff1909). They also receive inputs from other sensory systems aswell as from the forebrain, brain stem centers, and spinal cord(Deliagina et al. 1993; Dubuc et al. 1993; Rovainen 1967, 1979;Viana Di Prisco et al. 1995; Wickelgren 1977). In the spinal cord,RS neurons affect motoneurons and different classes of interneurons(Brodin et al. 1988; Ohta and Grillner 1989; Rovainen 1967, 1974,1979; Wannier et al. 1995; Zelenin et al. 2000b).

In earlier studies (Deliagina et al. 1992a; Orlovsky et al. 1992), responses of RS neurons to natural vestibular stimulation(roll tilt) and unilateral visual input (illumination of 1 eyeor electrical stimulation of the optic nerve) were investigatedin vitro in a preparation consisting of the brain stem isolatedtogether with the vestibular organs and eyes. It was found thatthe majority of RS neurons were activated with the contralateralroll tilt due to excitatory input from specific groups of thecontralateral vestibular afferents (Deliagina et al. 1992b). Theyexhibited both dynamic and static reactions within specific angularzones (Deliagina et al. 1992a). A unilateral visual input evokedexcitation of the ipsilateral and inhibition of the contralateralRS neurons in MRRN (Deliagina et al. 1993; Ullén et al. 1996).

The results of these in vitro experiments were recently confirmed in experiments on intact lampreys. The activity of RS neuronswas recorded from their axons in the spinal cord by means of implantedelectrodes (Deliagina and Fagerstedt 2000; Deliagina et al. 2000).It was found that the majority of recorded neurons (group 1) exhibitedvestibular responses (activation with contralateral tilt) similarto those observed in the in vitro experiments. Visual responses,that is activation with illumination of the ipsilateral eye andinhibition with illumination of the contralateral eye, were alsosimilar.

After the commands for postural corrections transmitted by the RS system have been characterized in sufficient detail in intactanimals, we can address the question of how these commands aremodified in the animals subjected to UL. In the present study,we examined the vestibular responses in individual RS neuronsbefore and after UL. We also analyzed the effect on these responsesproduced by unilateral eye illumination, that is by the factorthat causes immediate restoration of postural control in ULanimals.

A brief account of this study has been published in an abstract form (Deliagina 1997c).

	METHODS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Experiments were carried out on 12 adult (25-35 cm in length) intact lampreys (Lampetra fluviatilis), which were kept in anaerated freshwater aquarium at 7°C, with a 12 h:12 h light:darkcycle.

Electrodes

The activity of RS neurons was recorded from their axons in the spinal cord by means of chronically implanted macroelectrodesas described in detail in the previous papers (Deliagina and Fagerstedt2000; Deliagina et al. 2000). In short, the electrodes (silverwires 75 µM in diameter and 3 mm in length) were oriented in parallelto the long spinal axons. They allowed an almost exclusive recordingof the spike activity from larger fibers that have a conductionvelocity of more than 2 m/s. In the lamprey, only RS pathwayscontain fibers with such a high conduction velocity. The electrodeswere glued to a plastic plate (6 mm long, 2 mm wide, and 0.25mm thick). Three different designs of the electrode array wereused: four electrodes, two electrodes, and two electrodes separatedby an isolating wall. The wall was then positioned in an incisionbetween the two halves of the spinal cord to record separatelyfrom the left and right RSpathways.

Surgery

The effect of UL was studied in eight animals, which were operated on two times under MS-222 (Sandoz) anesthesia (100 mg/l).During the first surgery, implantation of the electrodes was performedas described in detail by Deliagina et al. (2000) and by Deliaginaand Fagerstedt (2000). In five of these eight animals, two plateswith electrodes were implanted at different rostrocaudal levels.The plate with two electrodes was implanted at the level of thethird gill and the plate with four electrodes 20-30 mm more caudally.The electrodes were facing the dorsal aspect of the spinal cord(see Fig. 1A, inset). In three of these eight animals, only oneplate with two electrodes separated by a longitudinal wall wasimplanted at the level of the last gill.

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Fig. 1. Vestibular responses in reticulospinal (RS) pathways and in individual RS axons before and after unilateral labyrinthectomy (UL) (animal G4). A and D: mass activity of RS axons elicited by trapezoid roll tilting, $alpha$ , before (A) and after a unilateral (right) labyrinthectomy (D). The activity was recorded by 2 electrodes (5 and 6) of the rostral 2-electrode array and by 2 electrodes (1 and 4) of the caudal, 4-electrode array (inset in A). B and E, and C and F: superposition of the activity of 2 individual RS axons (neurons R8 and R6) extracted from the raw data (shown in A and B) with the spike sorting program, and recorded by 4 electrodes before and after UL (B, C and E, F, respectively); the display was synchronized by the "event" signal (Deliagina and Fagerstedt 2000

The UL was performed 2-3 days after implantation of the electrodes as described in detail earlier (Deliagina 1995, 1997a).In short, the hole was made in the dorsolateral aspect of thevestibular capsula, and the labyrinth was removed with a pairof fine forceps under visual control. After removal, the intactmedial wall of the vestibular capsule and a stump of the eighthnerve could be seen. Post mortem investigation showed that, inall cases, removal of the vestibular organ was complete, and themedial wall of the capsule wasundamaged.

All these eight animals, prior to the present study, had been also used in other studies: the animals with two implanted electrodearrays (n = 5) had been used for collecting data on the vestibularand visual responses in RS neurons (Deliagina and Fagerstedt 2000)and the animals with a single array (n = 3) for collecting dataon the activity of RS neurons during locomotion (Deliagina etal. 2000).

In addition to the main group of eight animals, in four animals, UL and implantation of electrodes (the 4-electrode arrayat the level of the last gill) were performed during one surgery.These animals were not used to characterize the effect of UL butrather to characterize the ipsi- and contralateral influencesof the labyrinth on RS neurons (see RESULTS).

Experimental protocol

In eight animals, vestibular and visual responses of RS neurons were examined two times $---$ on the next day after implantationof the electrodes and on the next day after UL. In the four animalssubjected to a single surgery, the responses were examined onlyafter UL. The arrangement for vestibular and visual stimulation,and the characteristics of stimuli have been described in theprevious paper (Deliagina and Fagerstedt 2000). Two patterns ofvestibular stimulation were used: alternating trapezoid tiltsto the left and to the right (see e.g., Fig. 2) and two full turnsabout the longitudinal axis (by 45° steps); the rotation in thefirst and in the second turn being performed in opposite directions(see e.g., Fig. 3). Illumination of each of the eyes could beperformed either separately or in combination with vestibularstimulation.

Data processing

Signals from the electrodes were amplified by conventional AC amplifiers, digitized with a sampling frequency of 10 kHz andstored on the hard disk of an IBM AT compatible computer by meansof data-acquisition software (Digidata 1200/Axoscope, Axon Instruments,Union City, CA). The recorded multiunit spike trains were separatedinto unitary waveforms, representing the activity of individualaxons, by means of data analysis software ("spike sorting," DatapacIII, Run Technologies, Laguna Hills, CA). The mediolateral positionof individual axons in the spinal cord was estimated by comparingthe amplitudes of the same spike recorded by electrodes of thesame array differing in their lateral position. In animals withthe electrodes implanted at two rostrocaudal levels (n = 5), theconduction velocity in individual axons could also be measuredusing the time delay between spikes from the same axon recordedby rostral and caudalelectrodes.

All the analytical procedures and possible sources of errors during the spike sorting have been described in detail in a previouspaper (Deliagina and Fagerstedt 2000) and are briefly summarizedin DISCUSSION. Besides the possible errors introduced by spikesorting, an additional possible source of errors in the presentstudy could have been a change in the recording conditions causedby displacement of the electrode arrays during the second surgicalintervention (UL). However, there were no marked changes in spikewaveforms following UL in any of eight experiments, as illustratedfor animal G4 in Fig. 1. Figure 1, A and D, shows the mass activityin RS pathways caused by trapezoid tilts and recorded by the rostraland caudal electrodes (5 and 6 and 1 and 4, see Fig. 1A, inset),before and after UL, respectively. These raw data were then analyzedby the spike sorting procedure (Deliagina and Fagerstedt 2000).Eight neurons with their axons on the right side of the spinalcord, and 11 neurons with left-side axons, were identified incontrol. After UL, all 11 left-side axons and 3 of the 8 right-sideaxons had not been identified. The remaining five right-side axonswere identified both before and after UL. Two of them, R8 andR6, are illustrated in Fig. 1, B and C and E and F, respectively,where the display was synchronized by the "event" signal (Deliaginaand Fagerstedt 2000). One can see that for each of the neuronsthe shape and absolute value of spike waveform in individual electrodes,the ratio between the spike amplitudes in different electrodes,and the time delay between the spikes in the rostral and caudalelectrodes, were not changed after UL (compare Fig. 1, B and E,as well as C and F).

	RESULTS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

In eight animals, the activity in RS pathways was recorded both before and after UL. The activity of individual axons wasthen separated from the mass activity, and all neurons were dividedinto two groups according to the criteria formulated earlier (Deliaginaand Fagerstedt 2000). Group 1 neurons (n = 47) were activatedby the contralateral tilt and by the illumination of the ipsilateraleye. Group 2 neurons (n = 8) were activated by tilt in any direction,and they could also respond to illumination of the ipsi- and/orcontralateral eye. It seems most likely that the neurons of group1, with clear-cut vestibular responses, carry information aboutspatial orientation of the animal, and play the major role inpostural control (Deliagina and Fagerstedt 2000). The role ofa small group 2, whose neurons' activity did not correlate withspatial orientation, is less clear. Evidently, neurons of thisgroup cannot directly participate in stabilization of any particularspatial orientation. However, the presence of weak and unspecificvestibular responses in these neurons suggests that they may slightlyaffect the level of excitability in spinal networks. Only group1 neurons will be considered in the followingtext.

Of the 47 group 1 neurons, 23 neurons were located on the side ipsilateral to the subsequent UL, and 24 neurons on the oppositeside. From 3 to 11 neurons were recorded in individual animals.For the cases when an axon was recorded by both rostral and caudalelectrodes (n = 22), the conduction velocity was calculated. Thevelocity ranged from 2.6 to 4.2 m/s.

Modifications of vestibular responses of individual RS neurons caused by UL and eye illumination

Data from the animal Ch23 is used to illustrate the modifications of vestibular responses in individual group 1 neurons causedby UL as well as the effect of contralateral eye illumination.In this animal, 8 of 11 recorded neurons belonged to group1.

Figure 2A shows the responses to trapezoid tilts in RS neurons of group 1 recorded before UL. Typically, these neurons weresilent before the stimulus was applied. The neurons of subgroup1R (R7-R9), with their axons located on the right side of thespinal cord, were excited with the contralateral (left) tilt.Their responses contained both a dynamic component (activity duringmovement) and a static component (discharge when a new positionwas maintained). The subgroup 1L neurons (L4-L6, L10, L11), withtheir axons on the left side, were excited with the right tilt.

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Fig. 2. Responses to trapezoid roll tilts in 8 RS neurons of group 1 (animal Ch23). Neurons of subgroups 1L and 1R had their axons located on the left and right side of the spinal cord, respectively. The responses were recorded before UL (A) and after UL (B). In B, a period of right eye illumination is indicated (upward deviation of the R eye trace). The database of this paper overlaps considerably with that of the previous paper. In particular, Figs. 2A and 3A are the modifications of Fig. 5, A and B, respectively, from Deliagina and Fagerstedt (2000)

Activity of the same neurons during two full turns is shown in Fig. 3A. In the first turn (rotation toward the contralaterallabyrinth), most subgroup 1L neurons exhibited a dynamic responsewith any change in position. In addition, a static response wasobserved within the zone between 45°R and 135°R. In the secondturn (rotation toward the ipsilateral labyrinth), the subgroup1L neurons exhibited almost no activity. The activity of the subgroup1R neurons mirrored that of the subgroup 1L neurons: they respondedin the second turn, both statically (in the zone between 45°Land 135°L) and dynamically. In the first turn, the activity ofsubgroup 1R neurons was much weaker than in the second turn. Thusthe two subgroups respond to rotation in opposite directions andhave different spatial zones of sensitivity.

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Fig. 3. Responses of the same neurons as in Fig. 1 to stepwise rotation. Two full turns in opposite directions were performed sequentially (1st turn and 2nd turn). Shaded columns (0°) indicate the normal (dorsal-side-up) orientation of the animal. The responses were recorded before UL (A) and after UL (B and C); in C, the right eye was continuously illuminated.

Figure 2B shows responses to trapezoid tilts in the same neurons recorded 1 day after the left labyrinth had been removed(see the 3 initial and 3 last tilt cycles performed in the absenceof visual stimulation). Responses in the subgroup 1R neurons (locatedon the undamaged side) disappeared after UL. In subgroup 1L, theresponses remained unchanged: the neurons were excited with thecontralateral tilt, and their responses contained both dynamicand staticcomponents.

Activity of the same neurons during two full turns is shown in Fig. 3B. The 1R neurons were not active at any position, whereasresponses in the subgroup 1L neurons remained almost unchangedif compared with the test before UL (Fig. 3A). The only differencewas a slight prolongation of the dynamic responses, and a slightwidening of the zones of static responses (45-180° against 45-135°beforeUL).

Illumination of the eye contralateral to UL strongly affected the vestibular responses in RS neurons. As shown in Fig. 2B,illumination of the right eye caused a re-appearance of the responsesto trapezoid tilts in the previously silent subgroup 1R neurons.By contrast, the responses in the subgroup 1L neurons were considerablyreduced, and their static component was almost completelyinhibited.

When tested by two full turns combined with right eye illumination (Fig. 3C), the responses of the subgroup 1R neurons werealso restored. As in the control before UL, the neurons were activatedin the second turn. However, their spatial sensitivity zones becamewider (45°R-135°L against 45°L-135°L before UL). Also the magnitudeof the response, and especially of its dynamic component, wassmaller than before UL. Eye illumination also led to a reductionof the response magnitude in the subgroup 1L neurons; especiallyaffected was the static component of theresponse.

Quantitative characteristics of the modifications of vestibular responses caused by UL and eye illumination

Because RS neurons were normally silent prior to stimulation, the effect of stimulation could be roughly evaluated by simplycounting the number of activated neurons. In Fig. 4, the compoundedheight of the bars indicates the total number of neurons on eachof the two sides (ipsilateral and contralateral to UL) that wereactivated by contralateral tilt under three conditions $---$ beforeUL, after UL but without eye illumination, and after UL duringillumination of the eye contralateral to UL.

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Fig. 4. Number of neurons (bar height) on the 2 sides (ipsilateral and contralateral to UL) that were activated by contralateral tilt under different conditions $---$ before UL (control), after UL without eye illumination (UL), and after UL during illumination of the eye contralateral to UL (UL + eye illum). Five populations of neurons could be distinguished (1-5); their numbers are shown as subdivisions of the bars: 1, neurons were present before UL as well as after UL under one or both lighting conditions (eye illuminated/not illuminated); 2, neurons were present only before UL; 3, neurons were present only after UL and only without eye illumination; 4, neurons were present only after UL and only with eye illumination; 5, neurons were present only after UL under both lighting conditions.

By tracking the activity of individual neurons under the three conditions, five populations of neurons (1-5) could be distinguished(Fig. 4). Neurons of population 1 were present before UL as wellas after UL with or without eye illumination. Neurons of population2 were present only before UL. Neurons of population 3 were presentonly after UL and only without eye illumination. Neurons of population4 were present only after UL and only with eye illumination. Finally,neurons of population 5 were present only after UL in both lightingconditions. This analysis has shown that 1) about 70% of the neuronsthat were activated before UL were also activated after UL whenthe eye was illuminated and 2) about a half of the neurons thatwere activated after UL were not activated before UL. 3) The ULcaused a threefold reduction in the number of responding neuronson the contralateral side and a slight increase of this numberon the ipsilateral side. Eye illumination caused a fourfold increaseof the number of responding neurons on the contralateral sidethat resulted in a restoration of "symmetry" in the ipsilateraland contralateralresponses.

To describe spatial zones of activity for the whole population of group 1 neurons under different conditions, we used twocharacteristics (Deliagina and Fagerstedt 2000): the percent ofsimultaneously active neurons as a function of the tilt angleand the frequency curve, that is, the average discharge frequencyof the responding neurons as a function of the tilt angle. Eachstep of the angular change was divided into three intervals (insetin Fig. 3A). Interval 1 corresponded to a movement from the precedingposition to a new one, and intervals 2 and 3 to a period whenthe new position was maintained. Both functions were calculatedseparately for each of the three intervals of each step and thenaveraged over all neurons activated in a given test in all eightanimals. The activity in the interval 1 was considered as a dynamicresponse, and the activity in the intervals 2 and 3 as an earlyand late static responses, respectively (Deliagina and Fagerstedt2000).

Figure 5, A₁ and B₁, shows the histograms of the relative number (percent) of simultaneously active neurons recorded beforeUL on the side ipsilateral to a subsequent UL (A₁) and on theopposite side (B₁). Along the horizontal axis the successive anglesof roll tilt during 2 turns (a and b), performed in opposite directionsin relation to the recorded neuron, are indicated. From thesegraphs, one can see that the responses recorded before UL on the2 sides were similar to each other; they were also similar tothe responses described in a previous paper (see Fig. 7A in Deliaginaand Fagerstedt 2000). During turn a, with rotation toward thecontralateral labyrinth, any change of orientation evoked a dynamicresponse in most RS neurons. During turn b, with rotation towardthe ipsilateral labyrinth, the dynamic responses were much weakerthan in turn a. Static responses were most pronounced in turna, in the positions 45°_co and 90°_co where up to 70% of the neuronswere activated. When the same positions were reached by rotationin the opposite direction (turn b), only a small proportion ofneurons was activated.

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Fig. 5. Summary of responses to full turn rotation in 2 subgroups of RS neurons $---$ ipsilateral to UL (A₁-A₃) and contralateral to UL (B₁-B₃). The responses were characterized by the relative number (percent) of active neurons as a function of roll angle. The angle of 0° corresponds to the dorsal-side-up orientation of the lamprey. The angular zones where the ipsilateral (i) or contralateral (co) labyrinth is facing downward are indicated. Rotation was performed toward the contralateral labyrinth in turn a and toward the ipsilateral labyrinth in turn b. In each of the angular steps, the dynamic response (activity during rotation) is shown by a black bar, the early and late static responses $---$ by 2 successive shaded bars. A₁ and B₁: responses before UL; A₂ and B₂: responses after UL without eye illumination; A₃ and B₃: responses after UL during illumination of the eye contralateral to UL. The responses were averaged over 8 tested animals and normalized to control. (Occurrence of responses exceeding 100% was due to an increase of the number of responding neurons after UL.)

Figure 6, A₁ and B₁, shows the frequency curves for the same populations of neurons recorded before UL on the side ipsilateralto a subsequent UL (A₁) and on the opposite side (B₁). The frequencycurves were similar to each other; they were also similar to thecurve obtained for group 1 neurons in a previous study (see Fig.7D in Deliagina and Fagerstedt 2000). The dynamic responses weremuch stronger than the static responses. Within the zone of maximalactivity (turn a, 45°_co-135°_co), the frequency in the dynamicresponses exceeded 8 Hz, whereas that in the static responseswas only 1-2.5 Hz.

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Fig. 6. Summary of responses to full-turn rotation in 2 subgroups of RS neurons $---$ ipsilateral to UL (A₁-A₃) and contralateral to UL (B₁-B₃). The responses were characterized by the average discharge frequency of active neurons as a function of roll angle. A₁ and B₁: responses before UL; A₂ and B₂: responses after UL; A₃ and B₃: responses after UL and during illumination of the eye contralateral to UL. The average frequency was calculated as the number of spikes generated by all active neurons in each of the intervals of the step and then divided by the number of active neurons and by the interval duration.

After UL, vestibular responses on the UL side, when characterized by the number of active neurons, slightly increased (compareFig. 5A, 1 and 2). However, the firing frequencies of active neuronsremained unchanged (compare Fig. 6A, 1 and 2). On the side contralateralto UL, vestibular responses dramatically decreased. The numberof responding neurons reduced several times (compare Fig. 5B,1 and 2) as well as the firing frequencies of active neurons (compareFig. 6B, 1 and 2).

Illumination of the eye contralateral to UL evoked substantial changes in the vestibular responses on both sides. On the ULside, the responses were reduced. When characterized by the numberof active neurons, a reduction of the static component can beseen (compare Fig. 5A, 2 and 3). When characterized by the firingfrequency of active neurons, a reduction of both components isevident (compare Fig. 6A, 2 and 3). On the side contralateralto UL and ipsilateral to the stimulated eye, illumination of theeye led to a partial restoration of vestibular responses, especiallyof their static component. Spatial zones of the restored responseswere similar to those observed before UL (compare Fig. 5B, 1 and3, as well as Fig. 6B, 1 and 3).

The major effect of UL, i.e., a dramatic reduction of vestibular responses in the contralateral neurons, and the major effectof eye illumination, i.e., restoration of these responses, wererobust and were observed in all eight animals. To evaluate theseeffects, we calculated a mean value of the response within thezone of maximal sensitivity (45-135°) under different conditions.The UL led to a reduction in this value by a factor of 23 in thenumber of active neurons, and by a factor of 17 in firing frequency.Eye illumination led to 100 or 51% restoration of the responsewhen it was characterized by the number of active neurons or firingfrequency,respectively.

Similar effects of UL and eye illumination were revealed when vestibular stimulation was performed by periodical trapezoidroll tilts. To characterize the responses, the cycle of simulationwas divided into six intervals (1-6 in Fig. 7), and the activityof neurons was calculated separately for each of the intervalsand then averaged (as described in the preceding text for thefull-turn rotation). In intact animals, RS neurons exhibited bothdynamic and static excitatory responses to contralateral tilt,as characterized by both the percent of active neurons (controlin Fig. 7, A₁ and B₁) and by their firing frequency (control inFig. 7, A₂ and B₂). UL caused moderate changes in the responseson the side ipsilateral to UL (UL in Fig. 7A, 1 and 2), but adramatic reduction in magnitude of the response on the contralateralside (UL in Fig. 7B, 1 and 2). Illumination of the eye contralateralto UL led to a considerable increase in the responses on the sidecontralateral to UL (UL + eye illum in Fig. 7B, 1 and 2). On theside ipsilateral to UL, eye illumination caused some decreaseof the response (UL + eye illum in Fig. 7A, 1 and 2).

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Fig. 7. Summary of responses to periodic trapezoid tilts in 2 subgroups of RS neurons $---$ ipsilateral to UL (A₁ and A₂) and contralateral to UL (B₁ and B₂). The responses were characterized by the relative number (percent) of active neurons (A₁ and B₁) and by the average discharge frequency (±SE) of active neurons (A₂ and B₂). The responses were recorded before UL (control), after UL with no eye illumination (UL), and after UL during illumination of the eye contralateral to UL (UL + eye illum).

Comparison of inputs to RS neurons from ipsilateral and contralateral labyrinths

Input from the contralateral labyrinth was considered in earlier studies as the major source of roll-dependent drive to RSneurons (Deliagina 1997a; Deliagina and Fagerstedt 2000; Deliaginaet al. 1993). This input is shown by solid lines in the conceptualmodel of the roll control system (Fig. 9A). The present studyhas demonstrated that input from the ipsilateral labyrinth canalso play a role under certain conditions (Figs. 5B₃ and 6B₃),thus confirming the earlier finding by Rovainen (1979) that RSneurons respond to electrical stimulation of both ipsi- and contralateralvestibular nerves. Experiments were performed to estimate a contributionof the two inputs to the roll-dependent activity of RS neurons.In the UL-lamprey, RS neurons were tonically activated by illuminatingthe ipsilateral eye (up to a firing frequency of 3-5 Hz), andthen a 90° tilt was performed. This test was done for the RS neuronson the side contralateral to the intact labyrinth to examine theircontralateral vestibular input and also on the side ipsilateralto the intact labyrinth to examine their ipsilateral input. Theresponses were normalized to the background firing rate inducedin the neurons by eye illumination. When the input from the contralaterallabyrinth was examined, the contralateral tilt (in relation toRS neurons) evoked an increase in activity up to 250% as comparedwith the background (Fig. 8A₁). With the ipsilateral tilt, theactivity decreased down to 20% (Fig. 8A₂). When the input fromthe ipsilateral labyrinth was examined, the contralateral tiltcaused an increase of the activity up to 150% (Fig. 8B₁); withthe ipsilateral tilt the activity decreased down to 20% (Fig.8B₂).

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Fig. 8. Vestibular inputs to RS neurons revealed in UL-lamprey. A₁ and A₂: inputs from the contralateral labyrinth revealed by tilts contralateral (A₁) and ipsilateral (A₂) to the recorded neurons. B₁ and B₂: inputs from the ipsilateral labyrinth revealed by tilts contralateral (B₁) and ipsilateral (B₂) to the recorded neurons. In all the tests, the neurons were initially activated by a continuous illumination of the ipsilateral eye; this activity was taken as 100% (controls, bar 1). The activity during tilt (dynamic component of the response, bar 2), and during maintenance of a new position (early and late static components, bars 3 and 4, respectively) was normalized to the control activity. The responses were averaged over 14 (A₁ and A₂) and 12 (B₁ and B₂) RS neurons recorded in 4 animals; mean values ± SE are shown.

Thus the two labyrinths supplement each other: each of them causes an increase of RS activity with contralateral tilt (Fig.8, A₁ and B₁), and a decrease with ipsilateral tilt (Fig. 8, A₂and B₂). The main action of the contralateral labyrinth is excitatoryin the sense that an increase of RS activity with contralateraltilt (Fig. 8A₁) is larger than a decrease of this activity withipsilateral tilt (Fig. 8A₂). The main action of the ipsilaterallabyrinth is inhibitory in the sense that a decrease of RS activitywith ipsilateral tilt (Fig. 8B₂) is larger than an increase ofthis activity with contralateral tilt (Fig. 8A₂).

From Fig. 8 it can also be seen that the excitatory action of the contralateral labyrinth on RS neurons is much stronger thanthat of the ipsilateral labyrinth. The inhibitory actions of thetwo labyrinths are similar in strength, i.e., they cause a three-to fourfold decrease in the backgroundactivity.

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Possible errors caused by spike sorting and by instability of recording conditions

A detailed analysis of possible errors caused by the spike sorting procedure was given in the previous paper (Deliagina andFagerstedt 2000). In brief, discharges in individual axons wereseparated (clustered) on the basis of multiple criteria: simultaneousoccurrence of spike in all electrodes of the array, constancyof the spike waveform in each electrode, constancy of the axonposition in the spinal cord, and constancy of the axonal conductionvelocity. Due to the multitude of criteria, both possible typesof errors in clustering, i.e., misidentification and loss of spikes,were reduced considerably. An estimate for these errors was obtainedwhen the same cluster of units was separated on the basis of inputsfrom different combinations of electrodes and even the electrodesfrom the rostral and caudal arrays. It was found that the differencein the number of spikes in a cluster was always less than 20%.These errors might lead to the corresponding errors in the meanfiring frequency of RS neurons. However, such small errors infrequency could not affect any principal conclusions of the presentstudy, that is a disappearance of the response to tilt in onesubgroup of RS neurons caused by UL, and its restoration whenthe eye was illuminated (see RESULTS).

As judged from minor changes of the spike waveform in the RS neurons identified both before and after UL (Fig. 1), the surgicalintervention had practically no effect on the recording conditionsfor these neurons and, most likely, for other neurons. Thereforeit is very unlikely that the UL-caused disappearance of the activityin the contralateral RS neurons was caused by deterioration ofrecording conditions, especially when taking into account that,in most of these neurons, the activity could be restored by ipsilateraleye illumination. Similarly, the appearance of activity in "new"RS neurons after UL can hardly be attributed to the improvementof recording conditions specifically for these axons without affectingthe recording conditions for the neighboringaxons.

Modification of vestibular responses in RS neurons caused by UL and eye illumination: functional implications

Previous studies on in vitro preparations (Deliagina et al. 1992a,b, 1993) and intact animals (Deliagina and Fagerstedt 2000;Zelenin et al. 2000) led to formulation of a conceptual modelof the roll control system in the lamprey (Fig. 9A, connectionsshown by solid lines). The model was discussed in detail by Deliagina(1997a). In brief, the key elements of the model are the two subgroupsof RS neurons, the left [RS(L)] and the right [RS(R)]. The maininput to these neurons is the excitatory one from the contralaterallabyrinth. Because of this input, the activity of RS neurons isorientation dependent with its peak at approximately 90° of contralateralroll tilt (Fig. 9B₁). The two subgroups also receive an excitatoryinput from the ipsilateral eye and an inhibitory input from thecontralateral eye. It was suggested that each of the subgroups,via spinal mechanisms, elicits ipsilateral rotation of the lamprey(Fig. 9, A and B₁, arrows). The system will stabilize an orientationin space with equal activities of RS(L) and RS(R), that is, thedorsal-side-up position (equilibrium point in Fig. 9B₁).

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Fig. 9. Impairment of postural system caused by UL, and restoration of postural function caused by unilateral visual input. A: conceptual model of the roll control system as proposed earlier (solid lines) (see Deliagina and Fagerstedt 2000

), and its modifications based on the present study (interrupted lines). The signs (+ and $-$ ) indicate the major effects on RS neurons produced by sensory inputs, the signs in brackets indicate the minor effects. B₁-B₃: operation of the initial model under different conditions. The curves represent activity of the left and right subgroups of RS neurons as a function of roll angle. The presumed directions of rolling caused by RS(R) and RS(L) are indicated by the black and white arrows, respectively. B₁: control (intact lamprey). The 2 curves intersect, and the system has an equilibrium point at 0° (dorsal-side-up orientation). B₂: the right labyrinth removed (shown by a shaded rectangle in A). The system has no equilibrium point. B₃: effect of the left eye illumination. Visual input causes tonic activation of RS(L), and re-creation of the equilibrium point. C₁-C₃: activity of RS neurons on the 2 sides under different conditions as established experimentally in the present study. The curves represent the flow of impulses (the mean frequency multiplied by the number of active neurons) in the right and left subgroups of RS axons during the dynamic component of the vestibular response. C₁: control; C₂: the right labyrinth removed; C₃: effect of the left eye illumination. Graphs C₁-C₃ are based on Fig. 6. See text for further details.

The model could also explain the loss of equilibrium after UL. The model implies that UL causes inactivation of RS neuronson the contralateral side (Deliagina 1997a) as illustrated forthe right side labyrinthectomy in Fig. 9B₂. Because of the inactivationof RS(L), the two activity curves no longer intersect, the systemhas no equilibrium point, and the dominating RS(R) will causethe main postural deficit $---$ rolling of the lamprey to the right.This prediction of the model has been confirmed in the presentstudy. It was found that the two activity curves, which intersectedin intact animals (Fig. 9C₁), did not intersect after UL (Fig.9C₂). A divergence of the curves was caused not only by inactivationof RS(L) (as was predicted by the model) but also by some increaseof the response inRS(R).

The model could also explain the restoration of postural equilibrium with eye illumination. The model implies that an excitatoryinput from the eye contralateral to UL (Fig. 9A) can compensatefor the lacking vestibular input. This is illustrated in Fig.9B₃, where an upward translation of the RS(L) curve is due toan excitatory input to RS(L) from the illuminated left eye, anda downward translation of the RS(R) curve is due to an inhibitoryinput to RS(R) from the same eye. These modifications of the responseswill lead to a recreation of the equilibrium point in the systemand to a termination of rolling. This prediction of the modelhas also been confirmed in the present study. It was found thatthe two activity curves, which did not intersect without eye illumination(Fig. 9C₂), did intersect during continuous eye illumination (Fig.9C₃). A convergence of the curves was caused both by the upwardtranslation of the RS(L) curve and by the downward translationof the RS(R)curve.

In contrast to the prediction of the model, however, the RS(L) activity not only increased under the effect of visual inputbut also appeared to be roll-dependent. This finding indicatesthat RS neurons receive input not only from the contralaterallabyrinth but also from the ipsilateral one, thus confirming theearlier finding by Rovainen (1979). The latter input was not incorporatedin the initial version of the model. It has been characterizedin detail in the present study (Fig. 8) and is shown by the dottedlines in Fig. 9A. The input from the ipsilateral labyrinth supplementsthe main input from the contralateral labyrinth, and causes theroll-dependent changes in RS activity similar to those causedby the contralateral input, but of a smaller magnitude [compareRS(L) curves in Fig. 9C, 1 and 3].

Relevance of present results to vestibular compensation: comparison to other species

Experiments on mammals have shown that removal of a labyrinth has two major consequences. First, UL leads to elimination ofa tonic excitatory inflow from vestibular afferents on the damagedside to their brain stem targets, the neurons of the ipsilateralvestibular nuclei. Deprived of this input, these neurons reducedor even completely lose their tonic activity (Chen et al. 1999;Hamann and Lannou 1988; Precht 1974; Ris et al. 1997; Smith andCurthoys 1988a,b). This causes a imbalance between the activitylevels in the vestibular nuclei on the two sides as well as intheir targets in the brain stem and in the spinal cord, whichis probably the main factor responsible for postural disturbances(for discussion, see Deliagina et al. 1997; Smith and Curthoys1989). The present study has shown that, in the lamprey, UL alsoresults in a dramatic central asymmetry as monitored by the differencein the excitability levels of RS neurons on the two sides (seeFig. 9C₂). In the previous section, the arguments where presentedthat this asymmetry is the major cause for a loss of posturalequilibrium.

Another consequence of UL is a considerable reduction of the sensory inflow signaling head orientation; this inflow comesfrom one labyrinth in UL animals versus two labyrinths in intactanimals (Chen et al. 1999; Pompeiano et al. 1984; Xerri et al.1983). This will lead to a decrease of the gain in the posturalcontrol circuits and, consequently, to a reduction of posturalstability (for discussion, see Deliagina et al. 1997; Zennou-Azoguiet al. 1993). A similar effect of UL was observed also in thelamprey. When the central symmetry was restored by eye illumination,vestibular responses in RS neurons (characterizing the gain inthe brain stem circuits) were considerably smaller than in intactanimals (compare Fig. 9C, 1 and 3).

Studies on mammals have shown that compensation of the UL-induced motor deficits is associated with a restoration of the centralsymmetry as monitored by the recovery of activity in the deafferentedvestibular nuclei (Chen et al. 1999; Hamann and Lannou 1988; Precht1974; Ris et al. 1997; Smith and Curthoys 1988a,b). It seems mostlikely that restoration of the central symmetry is the main factorresponsible for the vestibular compensation (see, however, Riset al. 1997). In the UL lamprey, a unilateral eye illuminationis an experimental tool to immediately and reversibly restorepostural equilibrium (Deliagina 1997b). In the present study,we have found that eye illumination results in a restoration ofthe central symmetry (Fig. 9C₃). This finding strongly suggeststhat it is the restoration of the central symmetry, and the symmetryin RS commands addressed to the spinal cord in particular, thatis, responsible for postural recovery in the lamprey. To directlytest this hypothesis, however, recordings from RS axons duringthe period of compensation are necessary. This is the focus ofongoinginvestigations.

The method of recording the activity of RS neurons by means of implanted macroelectrodes, used in the present study, allowedus to track the activity of individual neurons under differentconditions, i.e., before UL, after UL, and also during restorationof the central symmetry caused by eye illumination. We have foundthat the populations of neurons responding to vestibular stimuliunder these different conditions overlap only partly (Fig. 4).In particular, under the two conditions when the lamprey can maintaina postural equilibrium (control and UL + eye illum in Fig. 4)the populations of active neurons strongly differed from eachother. This finding suggests that the recovery of postural controlafter UL is not necessarily related to the recovery of activityin the same population of RS neurons that was involved in posturalcontrol beforeUL.

	ACKNOWLEDGMENTS

The authors are grateful to Drs. G. Orlovsky, R. Hill, and P. Archanbault for valuable comments on themanuscript.

This work was supported by the Swedish Medical Research Council (Grant 11554), Royal Swedish Academy of Sciences, and CurtNilssonFoundation.

	FOOTNOTES

Address for reprint requests: T. G. Deliagina (E-mail: Tatiana.Deliagina{at}neuro.ki.se).

Received 18 April 2001; accepted in final form 2 October 2001.

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