Neurons of the Central Complex of the Locust Schistocerca gregaria are Sensitive to Polarized Light

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The Journal of Neuroscience, February 1, 2002, 22(3):1114-1125

Neurons of the Central Complex of the Locust Schistocerca gregaria are Sensitive to Polarized Light
Harm Vitzthum¹, Monika Müller¹, and Uwe Homberg²
¹ Institut für Zoologie, Universität Regensburg, D-93040 Regensburg, Germany, and ² Fachbereich Biologie, Tierphysiologie, Universität Marburg, D-35032 Marburg, Germany

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The central complex is a topographically ordered neuropil structure in the center of the insect brain. It consists of threemajor subdivisions, the upper and lower divisions of the centralbody and the protocerebral bridge. To further characterize therole of this brain structure, we have recorded the responses ofidentified neurons of the central complex of the desert locustSchistocerca gregaria to visual stimuli. We report that particulartypes of central complex interneurons are sensitive to polarizedlight. Neurons showed tonic responses to linearly polarized lightwith spike discharge frequencies depending on e-vector orientation.For all neurons tested, e-vector response curves showed polarizationopponency. Receptive fields of the recorded neurons were in thedorsal field of view with some neurons receiving input from bothcompound eyes and others, only from the ipsilateral eye. In additionto responses to polarized light, certain neurons showed tonicspike discharges to unpolarized light. Most polarization-sensitiveneurons were associated with the lower division of the centralbody, but one type of neuron with arborizations in the upper divisionof the central body was also polarization-sensitive. Visual pathwayssignaling polarized light information to the central complex includeprojections via the anterior optic tubercle. Considering the receptivefields of the neurons and the biological significance of polarizedlight in insects, the central complex might serve a function insky compass-mediated spatial navigation of theanimals.

Key words: polarized light; polarization vision; central complex; compass navigation; head direction; insect brain; locust; Schistocerca gregaria

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Insects can detect the polarization pattern of the blue sky and use it as a sensory cue for spatial navigation (for review,see Wehner 1992, 1994). The biological significance of polarizationvision for compass orientation has been most thoroughly studiedin desert ants (Wehner, 1994) and honeybees (Rossel and Wehner,1986; Rossel, 1993), but polarized light-dependent orientationhas also been demonstrated in several other insect species (forreview, see Stockhammer, 1959; Waterman, 1981). Photoreceptorsin a small dorsal rim area in the compound eye of many insectsare particularly adapted for polarized light detection and showhigh polarization sensitivity (for review, see Labhart and Meyer,1999).

Polarization-sensitive interneurons in the insect brain were first described in the optic lobe of the cricket, Gryllus campestris(Labhart, 1988; Labhart and Petzold, 1993; Labhart et al., 2001;Petzold, 2001). These neurons, like the photoreceptors of thedorsal rim area, are most sensitive to blue light. The neuronsshow polarization opponency, i.e., e-vector orientations causingmaximal excitation ( $Phi$ _max) are oriented perpendicularly to e-vectorscausing maximal inhibition ( $Phi$ _min). This feature indicates thatthe neurons receive antagonistic inputs from perpendicularly orientede-vector analyzers. Recently, polarization-opponent interneuronswere also found in the optic lobe of the desert locust (Hombergand Würden, 1997), the Madeira cockroach (Loesel and Homberg,2001), and the desert ant (Labhart, 2000).

In search for higher brain areas involved in sky compass orientation, we report here that certain interneurons in the locustcentral complex are polarization-sensitive. The central complexis a group of interconnected neuropils in the center of the insectbrain and includes the protocerebral bridge, the upper and lowerdivisions of the central body, and the paired noduli (Homberg,1987) (see Fig. 1A). Its most striking feature is a highly stratifiedinternal organization consisting of well defined layers in thecentral body and, perpendicularly, an arrangement into sets ofsixteen columns. Columnar neurons provide precise interhemisphericconnections and are the main output pathway from the central complexto the adjacent lateral accessory lobes. While the anatomicalorganization of the central complex has been unraveled in somedetail (Hanesch et al., 1989; Homberg, 1985, 1987, 1991; Wendtand Homberg, 1992; Vitzthum et al., 1996; Müller et al., 1997;Vitzthum and Homberg, 1998), its functional role is little understood.In moths, descending neurons from the lateral accessory lobesare involved in motor control such as steering maneuvers duringwalking and flight (Kanzaki et al., 1991, 1994), and behavioralanalysis of Drosophila melanogaster mutants with structural defectsin the central complex also support a role of the central complexin motor control (Strauss and Heisenberg, 1993; Ilius et al.,1994).

This study demonstrates a novel sensory aspect of signaling in the central complex. We show that neurons of the locust centralcomplex are sensitive to dorsally presented polarized light andsuggest an involvement of this brain structure in sky compassorientation.

Parts of this study have been published in abstract form (Müller and Homberg, 1994; Homberg and Müller, 1995; Vitzthum etal., 1997).

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Preparation. Experiments were performed on adult locusts (Schistocerca gregaria) obtained from a crowded laboratory colony.Animals were anesthetized by cooling and were waxed anterior uppermostto a metal holder. The heads of the locusts were immobilized bya wax-rosin mixture, and their legs were removed. For intracellularrecordings from the central protocerebrum, a small window wascut into the head capsule between the two compound eyes. The rightantenna and the median ocellus of the animal were removed. Afterremoving fat and some tracheal sacs, the midbrain was supportedand slightly lifted by a stainless steel platform that servedas the indifferent electrode. A small area of the midbrain wasdesheathed to facilitate microelectrode penetration. In some preparations,the recording site was stabilized further by a stainless steelring that was gently pushed onto the brain. In some recordings,especially when hemolymph pumping movements prevented stable recordings,the animals' head was cut off from the thorax. Successful recordingsfrom isolated heads were possible for up to 3 hr by perfusingthe preparation regularly with locust saline (Clements and May,1974).

Electrophysiology. Electrodes (resistance in the tissue, 80-200 M $Omega$ ) were drawn from glass capillaries (Hilgenberg, Malsfeld,Germany). They were filled either with 5% Lucifer yellow (MolecularProbes, Eugene, OR) or with 4% Neurobiotin (Vector Laboratories,Burlingame, CA) at the tip. Lucifer-filled electrodes were backedup with 0.1 M LiCl, and electrodes filled with Neurobiotin werebacked up with 1 M KCl. Electrodes were aimed at neural processesin the center of the brain close to the stump of the median ocellusat a depth of 150-200 µm from the frontal surface of the brain.Intracellular signals were conventionally amplified, monitoredwith an oscilloscope (Hameg, Frankfurt/Main, Germany) and storedon digital audio tape (DTR 1802; Biologic, Claix, France) foroff-line analysis. After recording, neurons were stained by iontophoreticinjection of Lucifer yellow with 0.5-5 nA constant hyperpolarizingcurrent or of Neurobiotin with 1-3 nA depolarizing current for3-20min.

Experiments were performed in dim ambient light (irradiance <0.1 µW/cm²). Stationary white light stimuli were produced by 150 W halogenlight sources (3200 K; infrared light excluded by heat absorbancefilters; cutoff wavelength, 724 nm). Light stimuli were deliveredto different parts of the visual field through flexible lightguides: (1) to the frontal binocular field of view (visual angle,14°; irradiance, 3.6 mW/cm²); (2) to the lateral field of view (right or left eye; visualangle, 3°; irradiance, 9 µW/cm²); and (3) to the dorsal field of view (zenith of the animal)through a neutral density filter (visual angle, 2.1°, irradiance,5 µW/cm²; in some experiments: visual angle, 8°; irradiance, 20 µW/cm²). To test for polarization sensitivity, the neutral density filterin the dorsal light path (3) was replaced by a Polaroid HN38Spolarization filter (Schlund, Zürich, Switzerland) with identicallight absorbance. e-vector orientations were changed stepwise(stationary stimulation) or continuously (rotatory stimulation)over a range of 180° or 360°. An e-vector orientation parallelto the body axis of the animal was defined as 0°. To test formotion sensitivity, a black and white square (half black, halfwhite; visual angle, 10°), and a black and white grating (32°× 72°; spatial wavelength, 9°) were moved by hand in various partsof the visualfield.

Data analysis. Physiological data were analyzed off-line using a CED 1401 plus interface and Spike2 software (Cambridge ElectronicDesign, Cambridge, UK). Parts of the recordings were printed witha laser printer. Background activities were determined as meanspike rates measured over 2-5 sec before experimental stimulation.To determine e-vector response curves from rotatory e-vector stimulations,means (±SD) of spike frequencies were determined in consecutive10° bins from two or four rotations (equal numbers of clockwiseand counterclockwise rotations) and plotted as a function of e-vectororientation. e-vectors eliciting maximal inhibition and excitation( $Phi$ _min and $Phi$ _max) were determined by fitting these plots to sin² functions. The fitting procedure was made by a least square fitthat followed the Levenberg-Marquardt algorithm (Origin 4.1 software;Microcal, Northampton,MA).

Histology. After physiological characterization and dye injection, brains were dissected out of the head capsule and immersedin fixative for at least 1 hr. Lucifer yellow-injected brainswere fixated in 4% paraformaldehyde in 0.1 M phosphate bufferat pH 7.4, whereas Neurobiotin required a fixative containing4% paraformaldehyde, 0.25% glutaraldehyde, and 0.2% saturatedpicric acid in 0.1 M phosphate buffer at pH 7.4. Lucifer yellow-injectedbrains were dehydrated through an ethanol series, cleared in methylsalicylate, and examined with a fluorescence microscope (Zeiss).For detailed anatomical examination, the brains were subsequentlyprocessed for Lucifer yellow immunocytochemistry by means of theindirect peroxidase antiperoxidase (PAP) technique (Sternberger,1986), as described by Homberg and Würden (1997). The Neurobiotin-injectedbrains were rinsed in PBS (0.01 M phosphate buffer; 0.45 M NaCl)with 0.1% Triton X-100 (Sigma, Deisenhofen, Germany), embeddedin gelatin-albumin, and sectioned at 30 µm with a Vibratome (TechnicalProducts, St. Louis, MO). The free-floating sections were incubatedfor at least 18 hr with Streptavidin conjugated to a polymereof horseradish peroxidase (Sigma), diluted at 1:2000 or with Streptavidinconjugated to horseradish peroxidase (Amersham Buchler, Braunschweig,Germany) at 1:200 in PBS with 0.5% Triton X-100. The sectionswere subsequently treated for 10-20 min with a solution of 3,3'-diaminobenzidinetetrahydrochloride (0.3 mg/ml) in 0.05 M Tris-HCl buffer, pH 7.4,with 0.3% nickel ammonium sulfate and H₂O₂ (0.015%). The sectionswere mounted and cleared like the Lucifer yellow-injected brains(Homberg and Würden, 1997). All neurons were reconstructed fromserial frontal sections by using a Zeiss microscope with cameralucida attachment. The terminology for brain structures largelyfollows the nomenclature of Strausfeld (1976) and, for centralcomplex subdivisions, Williams (1975), Homberg (1991), and Mülleret al. (1997). Positional information is given with respect tothe body axis of theanimal.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

This study is based on the characterization of 41 polarization-sensitive interneurons (POL neurons) of 140 neurons recordedand dye-injected in the median protocerebrum of the locust brain.Seventy-one percent of the recorded neurons either did not respondto any of the visual stimuli or, if they responded to light, didnot show e-vector-specific responses. Those neurons, furthermore,differed in morphology from the POL neurons, indicating that onlyspecific morphological types of neurons in the median protocerebrumare polarization-sensitive. Thirty-eight of the 41 POL neuronshad arborizations in the central complex. The three additionalPOL neurons innervated the lateral accessory lobes and/or theanterior optic tubercles of the protocerebrum, which are closelyassociated with the central complex. Nine recordings from POLneurons were obtained from isolated head preparations (indicatedin the figure legends), and 32 recordings were from intact animalswith legs removed. No differences in response characteristicswere observed between the two groups of animals. None of the POLneurons was sensitive to motionstimuli.

Three types of tangential neuron of the central body are polarization-sensitive

The upper and lower divisions of the locust central body are organized into distinct layers, which are primarily formed bythe arborization domains of tangential neurons (Müller et al.,1997; Homberg et al., 1999). Although the upper division of thecentral body is composed of three major layers (Homberg, 1991),a detailed study of the lower division showed that at least fivedistinct types of tangential neuron innervate single or severalof a total of six layers (Müller et al., 1997). Three types oftangential neuron showed polarization sensitivity (see Figs. 1-6).All of these neurons had arborizations in the lower division ofthe central body and could be identified as TL1, TL2, and TL3neurons (Müller et al., 1997), whereas a forth type, TL5 neuronswas not polarization-sensitive.

TL2 neurons

Polarization-sensitive TL2 neurons were encountered most frequently (13 recordings). The neurons had cell bodies in the inferiormedian protocerebrum. Dendritic arborizations were in a smallarea within the lateral accessory lobe of the brain termed thelateral triangle (Figs. 1A,B, 2A). Axonal projections were confinedto specific layers within the lower division of the central body.Twelve of the thirteen stained neurons had ramifications in thesecond upper layer (layer 2) of the lower division of the centralbody (Figs. 1,2) and only one neuron had arborizations in thelower layers 4/5 (data not shown). When giving flashes of unpolarizedwhite light in the dorsal visual field, eight TL2 neurons (61%)showed tonic inhibition of spiking activity (Fig. 1C), one neuron(8%) was tonically excited (Fig. 2B), and four neurons (31%) showedno clear response. Frontal or lateral light flashes were lesseffective than dorsal stimulation (Fig. 2B). Polarized light presenteddorsally elicited tonic excitations, tonic inhibitions, or nochange in spiking activity depending on the orientation of thepolarizer (Fig. 1C). Short rebound reactions often occurred afterexcitatory or inhibitory responses (Fig. 1C). The responses showedpolarization opponency, i.e., e-vectors eliciting maximal excitation( $Phi$ _max) were perpendicular to e-vectors eliciting maximal inhibition( $Phi$ _min) (Figs. 1C, 2B,C). When stimulating with a rotating polarizer,maximal spike activity occurred with a period of 180°, intersectedby periods of minimal spike activity, indicating again polarizationopponency (Fig. 2B). The response was independent of turning direction,and e-vector response plots revealed differences in $Phi$ _max of <10°,when comparing stationary and rotatory stimulation (data not shown). $Phi$ _max values differed widely within the 13 recorded neurons, andno classification was apparent (Fig. 2D). Considering the observationthat all but one neuron (which had $Phi$ _max at 102°) had ramificationsin layer 2 of the lower division of the central body, there isno evidence for an e-vector map represented by the layering ofthe lower division.

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Figure 1. Responses of a TL2 tangential neuron of the lower division of the central body to polarized light. A, Frontal diagram of the locust brain, indicating the position and subdivisions of the central complex in relation to other neuropil structures. AL, Antennal lobe; aL, $alpha$ -lobe of the mushroom body; AOTu, anterior optic tubercle; Ca, calyces of the mushroom body; CBL, CBU, lower and upper division of the central body; La, lamina; LAL, lateral accessory lobe; Lo, lobula; Me, medulla; P, pedunculus of the mushroom body; PB, protocerebral bridge; TC, tritocerebrum. Scale bar, 200 µm. B, C, Frontal reconstruction (B) and intracellular recording (C) of a Lucifer yellow-injected TL2 neuron of the central body. The neuron has its cell body in the inferior median protocerebrum. It innervates the lateral triangle (LT) of the lateral accessory lobe and layer 2 of the lower division of the central body (CBL). Scale bar, 100 µm. C, The neuron is tonically inhibited by dorsal unpolarized light (Li dors). It shows tonic excitation or inhibition to dorsal polarized light (Li dors pol) depending on e-vector orientation. Calibration: 10 mV, 1 sec.

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Figure 2. Responses of TL2 neurons to unpolarized and polarized light. A-C, Frontal reconstruction (A), intracellular recording (B), and e-vector response plot of a TL2 neuron, studied in an isolated head preparation. A, The neuron arborizes in the lateral triangle (LT) of the lateral accessory lobe (LAL) and in layer 2 of the lower division of the central body (CB). Scale bar, 100 µm. B, The neuron does not respond to illumination of the animal from frontal (front), right (re), or left (le) but is tonically excited by dorsal unpolarized light (dors). The neuron is completely inhibited by dorsal polarized light with e-vector orientation at 0° (dors 0°). Rotation of the polarizer through 360° results in alternating excitations and inhibitions, independent of turning direction. Calibration: 5 mV, 2 sec. C, e-vector response plot (means ± SD; n = 2, one clockwise and one counterclockwise rotation). Solid line indicates background activity. Fitting the data to a sin²-function (dotted line) reveals a $Phi$ _max of 88.4°. D, Distribution of $Phi$ _max from 13 recorded TL2 neurons.

TL3 neurons

TL3 tangential neurons (eight recordings) of the lower division of the central body had cell bodies intermingled with TL2neurons in the inferior median protocerebrum (Fig. 3B). Dendriticramification were confined to a second small area within the lateralaccessory lobe, the median olive, and consisted of tiny denseknots of fine processes typical of TL3 neurons (Fig. 3B). Arborizationsof most TL3 neurons in the lower division of the central bodywere confined to single layers. In seven preparations (88%), neuronshad projections in layer 5 of the lower division (Fig. 3B). Inone preparation, two TL3 neurons were simultaneously stained witharborizations in layers 2, 4, and 5 (data not shown). TL3 neuronshad low background spiking activity and, in contrast to most TL2neurons, responded with tonic excitation to unpolarized dorsallight (Fig. 3A). Lateral visual stimulation was without effect(Fig. 3A). Like TL2 neurons, TL3 neurons showed tonic responsesto polarized light, often with complete inhibition of spikingactivity at $Phi$ _min (Fig. 3A). The responses of all neurons showedpolarization opponency (Fig. 3A,C). $Phi$ _max-values varied greatlyamong the neurons, which indicates that no particular e-vectorpreference is represented in layer 5 of the lower division ofthe central body (Fig. 3D). The recording corresponding to thedouble-impaled TL3 neurons had $Phi$ _max at 146.9°.

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Figure 3. Polarization-sensitive TL3 neurons. A, Intracellular recording from a TL3 neuron (shown in B). The neuron is tonically excited by unpolarized dorsal light (dors) but does not respond to lateral stimulation from right or left (ri, le) eye. The neuron shows polarization opponency when the animal is stimulated dorsally through a rotating polarizer (trace 2) or with stationary polarized light (trace 3). Calibration: 30 mV, 2 sec. B, The neuron has minute processes in the median olive (arrows) of the lateral accessory lobe (LAL) and invades layer 5 of the lower division of the central body (CBL). Scale bar, 100 µm. C, e-vector response plot (means ± SD; n = 2). Background activity (solid line) is one spike per second. Sin²-fitting (dotted line) reveals a $Phi$ _max of 117.7°. D, Distribution of $Phi$ _max from eight TL3 neurons.

TL1 neurons

Five injections of polarization-sensitive neurons revealed TL1 tangential neurons of the lower division of the central body(Müller et al., 1997). The neurons had cell bodies in the ventromedianprotocerebrum. They invaded the lateral triangle of the lateralaccessory lobe with fine arborizations and had beaded terminalsthroughout layers 2-6 of the lower division of the central body(Fig. 4A). Most neurons showed high background activity of 10-15impulses/sec. The neurons either did not respond to unpolarizedlight or showed only weak excitations (data not shown). Dorsalstimulation with polarized light revealed, as for TL2 and TL3neurons polarization opponency (Fig. 4B). $Phi$ _max values were ~60°(56.4°, 60.5°), 100° (99.4°), and 170° (171.8°; 171.6°).

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Figure 4. Polarization-sensitive TL1 neurons. A, B, Frontal reconstruction (A) and e-vector-response plot (B) of a TL1 neuron. The neuron has its cell body in the ventromedian protocerebrum. Arborizations extend throughout the lateral triangle (LT) of the lateral accessory lobe and invade the lower division of the central body. CBU, Upper division of the central body. Scale bar, 100 µm. B, e-vector-response plot (means ± SD; n = 2). The neuron has a background activity of 12.6 impulses per second (solid line). Sin²-fitting (dotted line) reveals a $Phi$ _max of 99.4°. C, Distribution of $Phi$ _max from five TL1 neurons.

Other tangential neurons

Recordings from a variety of tangential neurons of the upper division of the central body did not reveal selective responsesto polarized light. Recordings from TL5 neurons of the lower divisionof the central body (n = 2), likewise, showed no evidence forpolarization sensitivity (Fig. 5). TL5 neurons had cell bodiesin the pars intercerebralis. Dendritic ramifications invaded theipsilateral hemisphere of the protocerebral bridge and the lateraltriangle of the lateral accessory lobe. Beaded terminals extendedthroughout the lower division of the central body (Fig. 5A). Inboth recordings, the neurons had high regular background activityof ~10 impulses/sec. One neuron showed a weak on-excitation tofrontal illumination (data not shown). The second TL5 neuron didnot respond to the visual stimuli including polarized light (Fig.5B).

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Figure 5. TL5 tangential neurons of the lower division of the central body are not sensitive to polarized light. A, Frontal reconstruction of a TL5 neuron. The neuron has its cell body in the pars intercerebralis. It innervates the ipsilateral hemisphere of the protocerebral bridge (PB), the lateral triangle of the lateral accessory lobe (LT), and all layers of the lower division of the central body. CBU, Upper division of the central body. B, The neuron shows regular background spiking activity and no response to frontal light (front) or polarized light with e-vector orientation rotating from 0° to 180°. Calibration: 5 mV, 1 sec.

TL2 and TL3 neurons differ in ocular dominance

Ocular dominance was tested in two TL2 and in three TL3 neurons. One compound eye was stimulated dorsally while the othereye was shielded from the light path through a piece of blackcardboard. The TL2 neurons showed polarization sensitivity irrespectiveof whether the ipsilateral or the contralateral eye was stimulated(Fig. 6A). One of the two neurons (Fig. 6A) showed a considerabledifference in $Phi$ _max for stimulation of the ipsilateral and contralateraleye ( $Phi$ _max-ipsi = 66.0°; $Phi$ _max-contra = 101.1°) and an intermediatevalue for binocular stimulation ( $Phi$ _max = 88.6°). In contrast, allTL3 neurons showed marked responses only when the ipsilateraleye was stimulated but no or only weak polarization sensitivityafter stimulation of the contralateral eye (Fig. 6B).

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Figure 6. Ocular dominance for polarized-light responses in TL2 and TL3 neurons. A, Responses of a TL2 neuron recorded in an isolated head preparation. Intracellular recording (left) and e-vector response plots (right) for stimulation of the ipsilateral and contralateral eye show that the neuron receives input from both compound eyes. Data from two 180° rotations of the polarizer are shown in the e-vector response plots. Solid lines: sin²-fit. Note considerable difference in $Phi$ _max for stimulation of the ipsilateral (66.0°) versus the contralateral (101.1°) eye. Stimulation of both eyes reveals an intermediate $Phi$ _max of 88.6° (data not shown). Calibration: 10 mV, 2 sec. B, Responses of a TL3 neuron recorded in an isolated head preparation. The neuron receives input almost exclusively from the ipsilateral eye. $Phi$ _max for ipsilateral and contralateral stimulation is nearly identical (66.6° and 66.1°) and matches $Phi$ _max for binocular stimulation (66.4°). Calibration: 5 mV, 2 sec.

Three types of POL neurons are columnar neurons of the central complex

In addition to a layered organization, the protocerebral bridge and the central body are subdivided from right to left intolinear rows of 16 columns, 8 columns in each hemisphere. Thesecolumns are innervated individually by columnar neurons. Mosttypes of columnar neuron described so far connect columns of thebridge to columns of the central body in a topographic manner,and, in addition, send axonal fibers to the lateral accessorylobes (Williams, 1975; Müller et al., 1997; Vitzthum and Homberg,1998). Columnar neurons were penetrated less frequently than tangentialcells, probably caused by their small fiber diameter. In total,six columnar neurons comprising three distinct cell types werefound to be polarization-sensitive. Each type of neuron was recordedand stained twice, and none of the neurons have been describedbefore.

One type of columnar POL neuron, termed columnar neuron of the protocerebral bridge type 1 (CP1) connected single columnsof the protocerebral bridge to the contralateral median oliveof the lateral accessory lobe (Fig. 7A). The second type of neuron,termed CP2, connected single columns of the protocerebral bridgeto the lateral triangle of the contralateral accessory lobe (Fig.7D). None of these neurons had arborizations in the central body.One CP1 neuron was weakly excited by unpolarized light (data notshown), and the others did not respond (Fig. 7C). All neuronsshowed tonic responses to polarized light with clear polarizationopponency (Fig. 7B,E).

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Figure 7. CP1 and CP2 neurons are polarization-sensitive. A-C, Frontal reconstruction (A), e-vector response plot (B), and responses to unpolarized light stimuli of a CP1 neuron. A, The CP1 neuron has its soma in the pars intercerebralis. It innervates the innermost column L8 in the left hemisphere of the protocerebral bridge (PB) and has arborizations throughout the median olive (MO) of the lateral accessory lobe (LAL). B, e-vector-response plot (means ± SD; n = 2). Solid line, Background activity. Sin²-fitting (stippled line) reveals a $Phi$ _max of 106.2°. C, The neuron shows no response to unpolarized light stimuli. Calibration: 20 mV, 2 sec. D, E, Reconstruction (D) and e-vector response plot (E) of a CP2 neuron. D, The neuron innervates column L4 in the left hemisphere of the protocerebral bridge and has arborizations throughout the lateral triangle of the lateral accessory lobe (LT). E, e-vector response plot (means ± SD; n = 2). Solid line, Background activity. Sin²-fitting (stippled line) reveals a $Phi$ _max of 13.0°.

Two columnar POL neurons, termed columnar neuron of the protocerebral bridge/upper division of the central body, type 1 (CPU1)had arborizations in the upper division of the central body. Theneurons had dense arborizations in single columns of the protocerebralbridge. A fiber projected through the posterior chiasm to thecentral body and had a second tree of ramifications in layer Iof the upper division of the central body. An axonal process gaverise to beaded arborizations throughout the lateral accessorylobe, but spared the lateral triangle and the median olive (Fig.8B). Both CPU1 neurons were weakly inhibited by ipsilateral andfrontal light pulses (Fig. 8A). Polarized light presented dorsallyresulted in tonic changes in spiking activity (excitatory or inhibitory)with pronounced rebounds after lights off (Fig. 8A). e-vectorresponse plots showed polarization opponency as in all other neuronsdescribed so far (Fig. 8C). The distribution of $Phi$ _max for the sixcolumnar neurons is shown in Figure 8D. All neurons invaded columnsin the left hemisphere of the protocerebral bridge, includingthe innermost column L8 ( $Phi$ _max = 106.2°) (Fig. 7A,B), column L6( $Phi$ _max = 102.2°) (Fig. 8), column L4 ( $Phi$ _max = 39.4°; 13°) (Fig.7D,E), column L2 ( $Phi$ _max = 5.6°), and a double impalement of twoCP2 neurons arborizing in columns L2 and L4 ( $Phi$ _max = 37.6°).

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Figure 8. Response properties of a CPU1 columnar neuron. A, Intracellular recording, showing tonic excitation (at 120°, 90°) or inhibition (at 30°, 0°, 180°) to dorsal polarized light. Note pronounced rebound reactions after lights off. Weak inhibitory responses also occur to illumination from frontal (front) and from the left (le) but not to light from dorsal and from the right (dors, ri). Calibration: 20 mV, 2 sec. B, Frontal reconstruction of the neuron. It innervates column L6 in the lateral hemisphere of the protocerebral bridge (PB), the innermost contralateral column in layer 1 of the upper division of the central body (CBU), and large areas in the contralateral accessory lobe (LAL). Scale bar, 100 µm. C, e-vector response plot (means ± SD; n = 2). Solid line, Background activity. Sin²-fitting (stippled line) reveals a $Phi$ _max of 102.2°. D, Distribution of $Phi$ _max from six columnar neurons of the central complex.

The anterior optic tubercles are part of the polarization-sensitive pathways to the central complex

Three recordings from POL neurons revealed neurons that innervated the lateral accessory lobes and/or the anterior optic tuberclesbut not the central complex. One neuron, named LAL1, connectedthe right and left lateral accessory lobes. Fine processes inone lobe were associated with the lateral triangle, and varicosearborizations on the other side were distributed throughout thelateral accessory lobe (data not shown). The second neuron (LAL2)(Fig. 9A) had its cell body in the inferior lateral protocerebrumclose to the anterior face of the brain. Dendritic ramificationswere in the upper division of the anterior optic tubercle andin posterior parts of the ipsilateral accessory lobe, includingthe median olive and lateral triangle. An axonal fiber crossedthe midline of the brain below the central body and innervatedthe contralateral accessory lobe with processes extending to themedian base of the contralateral optic tubercle (Fig. 9A). Thethird neuron (termed LoTu1) had nearly symmetrical arborizationsin both brain hemispheres (Fig. 9C). The cell body was in theinferior lateral protocerebrum. Dense fine arborizations wereconfined to the lower division of the anterior optic tubercleand via the anterior optic tract in a ventral layer of the anteriorlobe of the lobula complex. An axonal fiber crossed the midlinevia the intertubercle tract and invaded symmetric areas in thecontralateral hemisphere (Fig. 9C).

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Figure 9. Morphology and e-vector responses of POL neurons without arborizations in the central complex. A, Polarization-sensitive LAL2 neuron with arborizations in the upper division of the ipsilateral anterior optic tubercle (AOTu), wide arborizations in both lateral accessory lobes (LAL), and processes extending to the base of the contralateral anterior optic tubercle. Scale bar, 100 µm. B, Sin²-fitting (stippled line) of the e-vector response plot of the neuron (means ± SD; n = 4) revealed a $Phi$ _max of 167.4°. Solid line, Background activity. C, LoTu1 neuron with arborizations in the lower division of the anterior optic tubercle and in a ventral shell in the anterior lobe of the lobula complex of both brain hemispheres. aL, bL, Ca, P, $alpha$ -lobe, $beta$ -lobe, pedunculus, and calyces of the mushroom body. Scale bar, 100 µm. D, The neuron is excited by all e-vector orientations but the response magnitude depends on e-vector orientation. Sin²-fitting (dotted line) of the e-vector-response plot of the neuron (means ± SD; n = 4) reveals a $Phi$ _max of 79.0°.

Two neurons showed polarization opponency with inhibitory and excitatory responses depending on the orientation of the polarizer( $Phi$ _max = 12.1; 167.4) (Fig. 9B). The LAL1 neuron was inhibitedby dorsal unpolarized light, but excited by frontal light (datanot shown). The LoTu1 neuron, in contrast, was excited by alle-vector orientations. The response magnitude of LoTu1, however,clearly depended on e-vector orientation (Fig. 9D), and the e-vector( $Phi$ _max) eliciting maximal spiking activity was again perpendicularto the e-vector eliciting minimal excitation ( $Phi$ _min), like in polarization-opponentinterneurons.

POL neurons in the locust midbrain are not organized into defined classes of $Phi$ _max

POL neurons in the optic lobe of the cricket, studied by Labhart (1988) and Labhart and Petzold (1993) fell into three clearlydefined $Phi$ _max classes. In contrast, the distribution of $Phi$ _max fromPOL neurons in the midbrain of the locust (n = 41), includingneurons that could not be stained or that showed multiple dye-filledneurons show widely differing $Phi$ _max values without recognizableclasses (Fig. 10).

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Figure 10. Distribution of $Phi$ _max orientations from 41 recorded POL neurons in the median protocerebrum of the locust.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

In search for central mechanisms of sky compass orientation in insects, this study was aimed at identifying and characterizinghigher brain areas in the locust involved in polarization vision.We show that a subset of neurons in the central complex is sensitiveto dorsally presented polarized light. The neurons have, in part,overlapping branching patterns, and, therefore, may be synapticallyconnected. Staining of POL neurons without arborizations in thecentral complex, furthermore, suggests that the anterior optictubercles are involved in transmitting polarized-light signalsfrom the optic lobe to the centralcomplex.

Polarization vision in insects

Behavioral evidence for the detection of the plane of polarized light has been presented for a number of insect species, mostnotably honeybees (for review, see Rossel and Wehner, 1986; Rossel,1993), ants (for review, see Wehner, 1997), crickets (Brunnerand Labhart, 1987; Beugnon and Campan, 1989; Herz-mann and Labhart,1993), and backswimmers (Schwind, 1984). Polarization vision inthese insects is used either for sky compass navigation or, incase of the backswimmer and other aquatic insects, for the detectionof water surfaces. Accordingly, photoreceptors specialized forthe detection of polarized light are usually grouped in a ventraleye region (for the detection of water surfaces) or, more often,in a dorsal eye region, the dorsal rim area (for skylight navigation).Specialized dorsal rim areas have been found in a large numberof insect species, indicating that polarized skylight detectionis widespread in insects (Labhart and Meyer, 1999). Ommatidiain the dorsal rim area show prominent adaptations for polarizedlight detection, including changes in rhabdom shape, lack of retinalscreening pigment, homochromacy, and orthogonally arranged polarizationanalyzers (Nilsson et al., 1987; Labhart and Meyer, 1999).

Only a brief report has demonstrated polarization vision in locusts (Eggers and Weber, 1993). Locust larvae walking on a Kramersphere (Weber et al., 1981) showed menotactic orientation withrespect to e-vector orientation. Selective occlusion of variousparts of the eyes and ocelli showed that this behavior is mediatedthrough photoreceptors of the dorsal rim area. The dorsal rimarea of the desert locust differs markedly from adjacent areasof the compound eye (Eggers and Gewecke, 1993; Paech et al., 1997).Photoreceptors show high polarization sensitivity, are homochromaticblue-sensitive and, within each ommatidium, have perpendicularlyaligned microvilli. These features strongly suggest that locusts,like ants and bees, use polarization vision for skylight navigation,perhaps during long migratoryflights.

Processing of polarized light information in the brain

Little is known about the central processing of polarized light information in the insect brain. Polarization-sensitive interneuronshave been reported in the optic lobe of the cockroaches Periplanetaamericana and Leucophaea maderae (Kelly and Mote, 1990; Loeseland Homberg, 2001), the locust S. gregaria (Homberg and Würden,1997), and the desert ant Cataglyphis bicolor (Labhart, 2000),but an in-depth analysis only exists for the cricket Gryllus campestris(Labhart, 1988, 1996; Labhart and Petzold, 1993; Labhart et al.,2001; Petzold, 2001). As in the locust central complex, POL neuronsin the optic lobe of the cricket, cockroach, locust, and ant showedpolarization opponency. In the cricket, three classes of $Phi$ _maxwere found with orientations ~10°, 60°, and 130° to the longitudinalaxis of the animal. POL neurons in the cricket optic lobe wereindifferent to unpolarized light and had large visual fields (Labhart,1988; Labhart and Petzold, 1993). Anatomically, most recordingsin the cricket were from one type of commissural interneuron withdendritic arborizations in the dorsal medulla and an axonal projectionto the contralateral medulla, but other, less well characterizedtypes of neurons were also encountered (Petzold et al., 1995).

POL neurons in the locust central complex

Our study presents first evidence that the central complex, a major area in the median protocerebrum, is involved in the processingof polarized light. The morphological features of the recordedPOL neurons suggest that a particular network of interconnectedneurons within the central complex is involved in polarized lightsignaling. Common projection areas of the recorded POL neuronsinclude the protocerebral bridge, the lower division of the centralbody, and the median olive and lateral triangle of the lateralaccessory lobe. In contrast, only one type of POL neuron (CPU1neurons) had processes in the upper division of the central body.Tracer injections showed that the median olive and the lateraltriangle receive input from fibers originating in the anterioroptic tubercle (Hofer and Homberg, 2001). This connection andpolarization sensitivity encountered in neurons with ramificationsin the anterior optic tubercles strongly suggest that these brainareas are part of the polarization-vision pathway to the centralcomplex.

The recorded POL neurons of the central complex showed no preferences for certain $Phi$ _max orientations. This contrasts with thethree classes of $Phi$ _max orientations found in POL neurons in thecricket (Labhart, 1988; Labhart and Petzold, 1993). Furthermore,we did not find a correlation between $Phi$ _max and neuronal branchingpatterns. The occurrence of widely differing $Phi$ _max orientationsin TL2 and TL3 neurons innervating the same layer in the lowerdivision of the central body argues against an e-vector map encodedin the layering of the central body. The results for columnarneurons are less clear because of the small number of recordings.The functional significance of the 16-fold columnar organizationof the central complex, present in all insect species, is stillunclear (Homberg, 1987). The robust visual responses of columnarneurons, shown here for the first time, should now allow to analyzewhether this organization reflects a map for e-vector orientationsor for other parameters of theresponse.

An interesting aspect of signal processing in a neuropil like the central complex, which spans the midline of the brain, isthe integration of bilateral inputs. TL2 and TL3 neurons differedconsiderably in this respect. TL2 neurons received binocular inputand apparently pooled the signals from both eyes, whereas TL3neurons only responded to ipsilateralstimulation.

In contrast to POL neurons in the cricket optic lobe (Labhart and Petzold, 1993), many locust neurons showed, in additionto e-vector-specific responses, reactions to unpolarized light.This could mean that inhibitory and excitatory inputs from orthogonalpolarization analyzers are less well balanced than in the cricket.In an extreme case, excitatory light responses might merely bemodulated by inhibitory inputs at $Phi$ _min, as observed in the LoTu1neuron. Alternatively, the neurons might receive specific inputfrom nonpolarization-sensitive photoreceptors. In view of a possiblefunction of the central complex in sky compass orientation (seebelow), responses to unpolarized light in these neurons mightsignal the position of the sun or the spectral composition ofthe sky (Wehner, 1984, 1997), and thus could integrate additionalfeatures for sky compass navigation in theirresponse.

Functional role of the central complex

The central complex is one of the most prominent neuropil structures in the insect brain, yet its functional role has longbeen a mystery (Homberg, 1987). Accumulating evidence from brainstimulation and lesion experiments mainly in crickets (for review,see Homberg, 1987) single-cell recordings in the locust (Homberg,1994), behavior-dependent activity labeling (Bausenwein et al.,1994), and behavioral analysis of central-complex defects in thefly (Strauss and Heisenberg, 1993; Martin et al., 1999) suggesta role in the control of locomotor activity, particularly flightand walking. Mutations affecting the proper organization of theellipsoid body in Drosophila (equivalent to the lower divisionof the central body in the locust) and/or the protocerebral bridge,as well as targeted expression of tetanus toxin in neurons ofthese neuropils result in specific locomotor deficiencies. Theseinclude reduced locomotor activity, impairments in straightnessof walking, walking speed, and leg coordination during turns andstart-stops (Leng and Strauss, 1998; Martin et al., 1999).

Our present findings shed new light on the functional role of the central complex and, together with the evidence for a functionin motor control, point to a cardinal role in spatial navigationand direction coding. The responses to polarized light, presentedin the dorsal field of view, strongly suggest that the sky polarizationpattern is the biologically relevant stimulus for these neurons.Whereas polarized skylight provides directional information fromthe external environment (allothetic cues), information aboutself-movement (ideothetic cues) might be processed in the centralcomplex as well. Single-cell recordings, in fact, provide clearevidence for self-movement-generated mechanosensory input to thelocust central complex (Homberg, 1994). The balance of right-leftoutput from the central complex network might then control steeringcommands to thoracic motor centers. The role of descending neuronsfrom the lateral accessory lobes in right-left maneuvering has,in fact, been demonstrated clearly for the zig-zag walking pathof the silkmoth Bombyx mori toward a female (Olberg, 1993; Kanzakiet al., 1994; Kanzaki and Mishima, 1996; Kanzaki, 1998; Mishimaand Kanzaki, 1998). Taken the evidence together, we propose thatthe central complex is a center for direction perception and spatialnavigation and, therefore, is likely to exploit all informationavailable for that task including, in particular, the sky polarizationpattern.

  FOOTNOTES

Received July 17, 2001; revised Oct. 29, 2001; accepted Nov. 14, 2001.

This work was supported by Grants Ho 950/4 and Ho 950/13 from the Deutsche Forschungsgemeinschaft. We thank Dr. Monika Stenglfor insightful discussions and suggestions on thismanuscript.
Correspondence should be addressed to Dr. Uwe Homberg, Fachbereich Biologie, Tierphysiologie, Universität Marburg, D-35032Marburg, Germany. E-mail: homberg{at}mailer.uni-marburg.de.

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