Pigment-Dispersing Hormone Shifts the Phase of the Circadian Pacemaker of the Cockroach Leucophaea maderae

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Volume 17, Number 11, Issue of June 1, 1997 pp. 4087-4093
Copyright ©1997 Society for Neuroscience

Pigment-Dispersing Hormone Shifts the Phase of the Circadian Pacemaker of the Cockroach Leucophaea maderae

Bernhard Petri and Monika Stengl
Institut für Zoologie/Biologie I, Universität Regensburg, 93040 Regensburg, Germany

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

An antiserum against the crustacean neuropeptide pigment-dispersing hormone stains a small set of neurons in the optic lobesof several hemimetabolous and holometabolous insects. These cells,the primary branches of which in the optic lobe lie in the accessorymedulla, fulfill several criteria predicted for neurons of thecircadian clock. For example, in fruit flies they express timelessand period, which are two molecular components of the circadianpacemaker.
To test whether pigment-dispersing hormone fulfills a circadian function in the cockroach Leucophaea maderae, 150 fmol ofsynthetic peptide was injected into the vicinity of the accessorymedulla. This resulted in a stable phase-dependent resetting ofthe phase of the circadian locomotor activity rhythm, which dependedon the amount of pigment-dispersing hormone injected. The resultingphase-response curve differs from that obtained with light pulses,suggesting that pigment-dispersing hormone-immunoreactive neuronsare not part of the visual input pathway to the pacemaker butan integral part of it and/or part of a nonphotic input into theclock. A possible role of these neurons in coupling the bilaterallypaired circadian pacemakers is discussed.
Key words: pigment-dispersing hormone; neuropeptides; circadian rhythms; phase shifts; pacemaker; insects

INTRODUCTION

The temporal structure of physiological and behavioral states is probably organized by internal clocks in all organisms. Inthe circadian system, this clock comprises a circadian pacemaker,which generates an endogenous rhythm of about 24 hr. The circadiansystem also includes an entrainment pathway for the synchronizationwith zeitgebers and output pathways to effector organs.

Lesion studies have localized bilaterally paired circadian pacemakers in the optic lobes, ventrally between medulla and lobulaof orthopteromorph insects such as the cockroach Leucophaea maderae(Nishiitsutsuji-Uwo and Pittendrigh 1968a,b; Roberts 1974; Sokolove1975; Wills et al. 1985; for review, see Page, 1985; Chiba andTomioka, 1987). These mutually coupled pacemakers control thephase and the period of the circadian locomotor activity rhythmas well as circadian changes in the sensitivity of the compoundeyes (Page et al., 1977; Page, 1978, 1982, 1983a; Wills et al.,1985; Colwell and Page, 1989, 1990). Both pacemakers can be entrainedby photoreceptors in or near the compound eyes (Roberts, 1965;Nishiitsutsuji-Uwo and Pittendrigh, 1968a; Page et al., 1977;Page, 1983a,b) and receive coupling input from the contralateralpacemaker (Page, 1981). However, the neuronal substrate of thecircadian pacemaker and its input and output pathways remain elusive.

A small discrete neuropil was discovered in the region where the lesion studies had located the circadian clock in hemimetabolousinsects (Homberg et al., 1991). This neuropil, which was termedthe accessory medulla (AMe), is innervated by a small group ofneurons with adjacent somata, which are immunoreactive with anantiserum against the neuropeptide pigment-dispersing hormone(PDH) (Homberg et al., 1991). These PDH-immunoreactive neuronsfulfill morphological criteria predicted for elements of the circadiansystem such as the specific location of their somata and primarybranching areas in the optic lobes and arborizations in severalareas of the midbrain (Sokolove, 1975; Page, 1985; Homberg etal., 1991; Nässel et al., 1991; Stengl and Homberg, 1994). Mass-stainingtechniques such as immunocytochemistry, however, cannot discernthe branching patterns of individual PDH-immunoreactive neurons.Intracellular recordings and Lucifer yellow staining of singleneurons suggest that individual PDH-immunoreactive neurons differin their morphologies and functions (Würden and Homberg, 1994;Lösel and Homberg, 1996). Recent experiments in cockroaches,crickets, and flies suggest the following functions for differentindividual PDH-immunoreactive neurons: (1) they could be the neuronsof the light entrainment pathway (Homberg et al., 1991; Würdenand Homberg, 1994; Lösel and Homberg, 1996); (2) they could beoutput pathways to the effectors of the clock (Helfrich-Försterand Homberg, 1993; Stengl and Homberg, 1994; Pyza and Meinertzhagen,1995, 1996; Stengl, 1995; Meinertzhagen and Pyza, 1996; Helfrich-Förster,1997); (3) they may couple the bilaterally paired optic lobe pacemakers(Stengl and Homberg, 1994); and (4) they may themselves be anintegral part of the pacemaker (Helfrich-Förster, 1995).

This study examines the functions of PDH, the presumptive neurotransmitter and neuromodulator of PDH-immunoreactive neurons,via injection of a peptide into the vicinity of the AMe. We showthat PDH specifically shifts the phase of the pacemaker that drivesthe circadian wheel-running activity rhythm of L. maderae. Ourresults cannot distinguish between the functions of differentindividual PDH-immunoreactive neurons, but they suggest that atleast some of these neurons are an integral part of the pacemakerand/or part of a nonphotic input.

MATERIALS AND METHODS
Beavioral assays and data analysis. L. maderae cockroaches were reared in laboratory colonies at 30°C, 30% humidity, and light/darkcycles of 12:12 hr (with lights on from 6 A.M. to 6 P.M.). Onlymales were chosen for the experiments (n = 141), because theyexpressed a more robust circadian locomotor activity rhythm thanfemales. Behavioral analysis was performed in constant darkness(DD), at constant temperature (28 ± 0.5°C), and constant humidity(70%). Experimental animals were continuously provided with food(dry rat pellets) and water. Locomotor activity was recorded inrunning wheels (modified from running wheels provided by Dr. WolfgangEngelmann, University of Tübingen, Tübingen, Germany; describedby Wiedenmann, 1977) equipped with a magnetic reed switch. Onerevolution of the running wheel resulted in one impulse. The impulseswere continuously counted by a microcomputer in 1 min intervalsand condensed and processed by custom made PC-compatible software(developed by H. Fink, University of Konstanz, in collaborationwith Drs. M. Stengl and F. Wollnik). This software allows an on-linevisualization of the raw data in activity histograms as well as $chi$ ² periodogram analysis. The data were plotted in double plot activityhistograms. The heights of the bars represent the number of revolutionsper 5 min; they were cut off at 30 rpm.

The free-running period, $tau$ , and the induced phase shifts were estimated by converting the raw data into ASCII format. Theywere then merged into 20 min intervals and analyzed with CHRONOII software (generously provided by Dr. Till Roenneberg; see Roennebergand Morse, 1993) on an Apple Macintosh computer (data were obtainedfrom 104 animals). The remaining 37 animals were excluded fromfurther analysis because they showed little activity after theinjection or died within 1 week after the operation.

The free-running period $tau$ before and after the injection was calculated by linear regression through daily activity onsetsand by $chi$ ² periodogram analysis (Sokolove and Bushell, 1978; Enright, 1965).Changes in free-running period $tau$ ( $Delta$ $tau$ = $tau$ _after $-$ $tau$ _before) werecalculated with periods estimated by regression through activityonsets. Phase shifts ( $Delta$ $phi$ ) were estimated by measuring the timedifference between the regression lines before and after the injectionextrapolated to the day of the treatment (Fig. 1). These phaseshifts were then normalized with respect to the free-running period $tau$ before the treatment. Phase delays are plotted as negative values,and phase advances are plotted as positive values. Daily activityonsets were determined by CHRONO II (see Roenneberg and Morse,1993). The time on the x-axis was indicated as circadian time(CT), with CT 12:00 = activity onset = beginning of the subjectivenight.
Fig. 1. Records of circadian wheel-running activity and plots of activity onsets from cockroaches kept in constant darkness. A, B,After an injection of 46 fmol of synthetic PDH in 0.5 nl of salineat CT 13:00 of day 19 (arrowhead), regression analysis throughconsecutive activity onsets (B) reveals a resulting phase delayof $-$ 0.4 circadian hr (h_CT) after the injection. C, D,Injection of 46 fmol of synthetic PDH in 0.5 nl of saline at CT9:00 of day 12 (arrowhead) induces a phase delay of $-$ 4.3 circadianhr (h_CT). A-D, In both experiments, no effect on theperiod $tau$ of the activity rhythm is apparent. x-axis, Time of theday; y-axis, days.
[View Larger Version of this Image (38K GIF file)]

The microinjection data were merged into 2 hr intervals, and the means, SEM, and SD were calculated. Changes in phase andperiod in a given interval were considered significantly differentfrom 0 when the calculated 95% confidence interval (CI) of thatinterval did not contain the value 0 (Sachs, 1969). The phase-responsecurves were analyzed by one-way ANOVA with Scheffé's multiplerange test. Significance in all cases was defined as p < 0.05.Statistical analyses were performed with Superior Performing SoftwareSystems (SPSS Inc.) on a personal computer.

Operation and injection.All manipulations were performed in dim red light at room temperature (25°C) with a Microinjector(model 5242; Eppendorf, Hamburg, Germany). Experimental animalswere removed from the running wheels and mounted in metal tubesat different times during the circadian cycle. After anesthetizingthem with CO₂, a small window was cut into the head capsule, andthe optic lobe was revealed by moving the trachea, ocellus, andfat body carefully to the side. The neurolemma of the optic lobewas penetrated with a borosilicate glass capillary (Clark, PangbourneReading, England), and the neuropeptides were pressure injectedunder visual control into one medulla, dorsally and distally tothe AMe (Fig. 2). The region of the AMe can be localized accuratelyusing external landmarks such as the trachea shown in Figure 2.After the injection the removed piece of cuticle was waxed back,and the animal was returned to the running wheel. Each treatmentlasted 10-15 min. All injections targeted only one optic lobe,whereas the other lobe was left intact. It was known from earlierstudies that both bilaterally symmetric pacemakers are tightlycoupled in cockroaches (Page, 1981, 1985). This means that anydisturbance of one pacemaker will be transferred to the otherone and will result in a phase shift of the locomotor activityrhythm (which, therefore, is controlled by both coupled pacemakerstogether). All experimental animals were kept under constant conditions(DD) before and after the injection.
Fig. 2. Schematic drawing of the different PDH injection sites. PDH was pressure injected via glass microcapillaries into the vicinityof the AMe. Each dot represents the location of one injection,as assessed by visual control during the experiment (n = 57).A characteristic trachea at the surface of the optic lobe (arrowhead)was used as a landmark. Me, Medulla; La, lamina; Lo, lobula. Scalebar, 200 µm.
[View Larger Version of this Image (13K GIF file)]

Because PDH from L. maderae has not been sequenced yet, neuropeptide injections consisted of 10⁴-10¹² M synthetic Arg¹³-Acheta domestica PDH (NSEIINSLLGLPRVLNDA-amide; generously providedby Dr. K. R. Rao, University of West Florida, Pensacola, FL) in10% aqueous blue food dye (McCormick, Baltimore, MD), which madethe exact site of the injection visible without the need for furtherneuroanatomical processing of the brain. The purity of the syntheticpeptide was examined by HPLC and by quantitative amino acid analysis(performed by R. Rao and associates). A peptide concentrationof 10⁴ M was used for obtaining the phase-response curve. Concentrationsof 10⁸ and 10¹² M PDH were also tested to plot the dose-response curve. Eachmicropipette was calibrated by estimating the injected volume.Droplets were injected into mineral oil before and after the injectionto control for changes in tip diameter during penetration of theneurolemma. The injected volume for all 104 injections rangedfrom 0.5 to 2 nl with a mean dose of 1.5 ± 0.6 (SD) nl. Controlinjections consisted of 10% aqueous blue food dye without PDH.

RESULTS

Effects of PDH injections on the phase of the circadian locomotor activity rhythm
Control injections of blue food dye caused no significant phase change in circadian locomotor activity or rhythm, regardlessof when in the circadian cycle it was injected (Table 1). Microinjectionsof synthetic PDH (n = 57) into the medulla resulted in time-dependentphase shifts of the circadian activity rhythm of L. maderae (Figs.1, 2, Table 1). Maximal phase delays ( $-$ 4.7 hr) occurred whenPDH was given late in the subjective day (CT 8:50), and maximalphase advances (1.8 hr) occurred with injections late in the subjectivenight (CT 19:30) (Fig. 3A). Examination of the 95% confidenceintervals (95% CIs) for the phase shifts in different 2 hr bins(see Materials and Methods) indicates that significant peptide-dependentphase shifts occurred at CT 6:00-14:00 (Table 1, ^b). The shifts during the rest of the cycle, including the phaseadvances, were not significant.

Table 1. Phase shifts (mean ± SEM in circadian hours) resulting from PDH and control injections at different times of the circadiancycle (circadian time)

Injection Circadian time Phase shift 95% CI n

PDH 00:00 -02:00 0.8 ± 0.2^a $-$ 0.3 to 1.8 3

02:00 -04:00 0.3 ± 0.1^a $-$ 0.1 to 0.6 5

04:00 -06:00 $-$ 0.2 ± 0.4^a $-$ 2.1 to 1.7 3

06:00 -08:00 $-$ 1.1 ± 0.3^a $-$ 2 to $-$ 0.2^b 5

08:00 -10:00 $-$ 3.2 ± 0.4^c,d $-$ 4 to $-$ 2.2^b 11

10:00 -12:00 $-$ 2.2 ± 0.5^d $-$ 3.4 to $-$ 1^b 6

12:00 -14:00 $-$ 1.4 ± 0.2^a $-$ 1.7 to $-$ 0.9^b 8

14:00 -16:00 $-$ 0.9 ± 0.4 $-$ 6 to 4.2 2

16:00 -18:00 0 ± 0.3^a $-$ 0.8 to 0.8 5

18:00 -20:00 0.6 ± 0.5^a $-$ 0.8 to 2.1 5

20:00 -22:00 0.7 ± 0.4^a $-$ 0.7 to 2 4

Control 08:00 -10:00 0 ± 0.2 $-$ 1 to 1 3

10:00 -12:00 $-$ 0.3 ± 0.1 $-$ 0.6 to 0.1 5

00:00 -24:00 $-$ 0.2 ± 0.1 $-$ 0.4 to 0.1 35

^a PDH-dependent phase shifts significantly different from that at circadian time 08:00-10:00. ^b Statistically significant phase shifts after PDH injections, as judged by the 95% CI (see Materials and Methods). ^c Phase shifts additionally significantly different from PDH-dependent phase shifts at other circadian times (^a) (p < 0.05, Scheffé's multiple range test). ^d PDH-dependent phase shifts that are significantly different from control injections (p < 0.05 Scheffé's multiple range test).

Fig. 3. Scatter plot of PDH-dependent phase shifts at different times in the circadian cycle. A, The PDH injections (150 ± 60 fmolin 1.5 ± 0.6 nl of saline, mean ± SD; n = 57) cause maximal phasedelays during the late subjective day ( $-$ 4.7 hr at CT 8:50) andmaximal phase advances during the late subjective night and earlysubjective day (1.8 hr at CT 18:30). The phase advances were notstatistically significant. B, Independent of the time of day,control injections (0.5-2 nl of saline; n = 35) caused only smallphase delays and phase advances, which were not statisticallysignificant. Each point represents the phase shift (in circadianhours) resulting from a single injection. Phase advances are alwaysshown as positive values, and phase delays are shown as negativevalues.
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This phase dependency was statistically significant (p < 0.00005, one-way ANOVA), because PDH-dependent phase delays at CT8:00-10:00 were significantly different from PDH-dependent phaseshifts during other times of the circadian cycle (Table 1, ^c, Fig. 4). In addition, delays induced by PDH injections at CT8:00-10:00 and 10:00-12:00 were significantly different from theeffects of the control injections at the same circadian times(Table 1, ^c,d, Fig. 4). Effects of control injections in different intervalswere not significantly different from each other (p = 0.7, one-wayANOVA), and in no case were they significantly different from0 hr (Table 1).
Fig. 4. Phase-response curves obtained with PDH or control injections. Data from Figure 3 were merged into 2 hr bins. The PDH-dependentphase shifts (closed squares) and phase shifts after control injections(open circles) are plotted (mean ± SEM) in the middle of each2 hr bin. All filled stars indicate PDH-dependent phase delaysthat are significantly different from phase shifts following controlinjections. Furthermore, PDH-dependent phase delays at CT 8:00-10:00(double star) are significantly different from PDH injectionsat other circadian times (open stars) (p < 0.05, Scheffé's multiplerange test).
[View Larger Version of this Image (25K GIF file)]

Effects of PDH injections on the period of the circadian locomotor activity rhythm
No significant changes in the free-running period (Fig. 1) of individual experimental cockroaches after the injection of eithersaline or PDH were found (p = 0.6, one-way ANOVA). The effectsobserved were always small and included both lengthening (by maximally0.3 hr) and shortening (by maximally $-$ 0.4 hr) and were independentof the time of injection in the circadian cycle. On average, themean period (23.4 ± 0.2 hr, mean ± SD; n = 92) was not alteredeither by PDH or by control injections (0 ± 0.2 hr, mean ± SD;95% CI, $-$ 0.1 to 0.1 hr; n = 92). In four experiments (as in Fig.1C) the period up to 10 days after the injection seemed longerthan the average period. However, because of little overall activityafter the operation, we were not able to confirm this observationby periodogram analysis.

Dose dependency of PDH-dependent phase shifts
Microinjection of synthetic PDH into the optic lobes of cockroaches at CT 8:00-10:00 caused phase delays in circadian wheel-runningactivity that depended on the dose of PDH injected (Fig. 5). Thephase delays decreased with decreasing amounts of injected PDH.Significant phase delays (Fig. 5, stars) were caused by injectionof 150 fmol PDH ( $-$ 3.1 ± 0.4 hr; 95% CI, $-$ 4 to $-$ 2.3 hr; n = 11)and 15 × 10³ fmol PDH ( $-$ 1.5 ± 0.1 hr; 95% CI, $-$ 1.7 to $-$ 1.4 hr; n = 4). However,injection of 15 × 10⁷ fmol PDH caused phase shifts ( $-$ 0.3 ± 0.2 hr; 95% CI, $-$ 0.7 to0.2 hr; n = 8) that were indistinguishable from control injections( $-$ 0.2 ± 0.1 hr; 95% CI, $-$ 0.4 to 0.1 hr; n = 35) (p < 0.05, one-wayANOVA, Scheffé's multiple range test).
Fig. 5. Dose dependency of PDH-induced phase shifts between CT 8:00 and CT 10:00. Each bar represents the mean phase shift (in circadianhours ± SEM) resulting from injections of saline (n = 35), 15× 10⁷ PDH (n = 8), 15 × 10³ PDH (n = 4), and 150 fmol of PDH (n = 11) in 1.5 nl of saline.Stars indicate PDH doses that induced phase shifts significantlydifferent from control (saline) injections (p < 0.05, Scheffé'smultiple range test).
[View Larger Version of this Image (21K GIF file)]

DISCUSSION
Microinjections of the neuropeptide PDH into the vicinity of the AMe, the predicted pacemaker region, resulted in statisticallysignificant phase delays of the circadian wheel-running activityrhythm during the late subjective day. Therefore, the neuropeptidePDH seems to be a component of the circadian system of the cockroachL. maderae.

Our results, together with immunocytochemical studies (Homberg et al., 1991; Stengl and Homberg, 1994; Petri et al., 1995;Reischig and Stengl, 1996) indicate that PDH-immunoreactive processesin the AMe mediate nonphotic inputs into the clock and/or arean integral part of the pacemaking neuronal network. Further neuroanatomicalstudies on the light and electronmicroscopic level have to decipherthe individual branching patterns of individual PDH-immunoreactiveneurons with arborizations in the AMe that seem to fulfill thesefunctions.

Dose dependency of PDH-dependent phase shifts
The phase-dependent phase shifts of the locomotor activity rhythm in the late subjective day are specifically dependent onPDH, because they are dose dependent (Figs. 4, 5) and significantlydifferent from control injections. Furthermore, preliminary injectionsof another peptide (Mas-allatotropin) indicate that differentpeptides cause completely different phase-response curves (B.Petri and M. Stengl, unpublished observations). The thresholdfor PDH-dependent phase shifts lies between 0.015 and 1.5 × 10⁶ fmol of PDH. This seems to be a physiological dose level, becausesingle brains of orthopteromorph insects contain 1.2-50 pmol ofPDH, with about 90% of the PDH immunoreactivity concentrated inthe optic lobes (Rao and Riehm, 1993; S. Würden, personal communication).

So far, PDH-related peptides have not been sequenced from L. maderae, but comparison of the primary structure of PDH-relatedpeptides reveals a highly conserved sequence between crustaceansand different insects (Rao and Riehm, 1993). The PDH, which wasbiologically active in our experiments (Arg¹³-Acheta domestica PDH), differs only at two amino acid residues(positions 4 and 13) from the PDH of the cockroach Periplanetaamericana (Rao and Riehm, 1993). This suggests that a peptideclosely related to the A. domestica PDH is released by the PDH-immunoreactiveneurons of L. maderae.

A possible role of PDH-immunoreactive neurons as pacemaker neurons and/or input pathways to the pacemaker
Injection of PDH maximally delays the clock at times of the day when light has only weak effects, and conversely, PDH hasno effects at times when light advances the clock (Fig. 6) (Page,1987; Page and Barret, 1989). Therefore, it is unlikely that PDH-immunoreactiveneurons serve as photic input to the pacemaker.
Fig. 6. Phase-response curves for different phase-shifting signals in L. maderae. The phase-response curve for PDH is similar in shapeto the phase-response curve obtained for low temperature pulses(cold) (Wiedenmann, 1971) and serotonin infusions (5-HT) (Page,1987), but it is different from that obtained with light pulses(light) (Page and Barret, 1989).
[View Larger Version of this Image (25K GIF file)]

The phase-response curve obtained after PDH injections is comparable to the nonphotic phase-response curves obtained withserotonin or temperature pulses (Fig. 6) (Wiedenmann, 1977; Page,1987). All three phase-response curves are monophasic with themaximal delay region occurring at different times of the latesubjective day (Fig. 6) (Wiedenmann, 1977; Page, 1987). The phasedelay amplitude resulting from PDH injections is similar to thatcaused by serotonin pulses (Fig. 6) (Page, 1987), but the serotonincurve seems to have a broader peak. This is possibly attributableto different experimental methods. Page (1987) infused doses ofserotonin 7 log units higher than the PDH doses used here intothe hemolymph during periods of 6 hr. This may have resulted ina broadening of the delay peak. Because an excessive number ofindistinguishable 5-HT-immunoreactive neurons occurs in the opticlobes as well as in the midbrain, and because the branching patternsof the individual PDH-immunoreactive neurons are not known, itcannot be discerned whether PDH- and 5-HT-immunoreactive neuronsshare a common pathway into the AMe and/or whether they sharethe same postsynaptic neurons in the AMe.

Some PDH-immunoreactive cells seem to have morphologies suitable for providing nonphotic input to the clock, namely inputfrom the contralateral pacemaker. These PDH-immunoreactive neuronswith an unknown branching pattern in the optic lobe project throughthe posterior optic commissure into the contralateral optic lobeand might connect both accessory medullae directly. Current backfillsand degeneration experiments combined with immunocytochemistryon the light and electronmicroscopic level indicate that thereare projections from the contralateral optic lobe to the AMe andthat PDH-immunoreactive neurons form input as well as output synapsesin the AMe (T. Reischig and M. Stengl, unpublished observations).Because both accessory medullae are the presumptive pacemakingcenters in the cockroach (Homberg et al., 1991; Stengl and Homberg,1994; Reischig and Stengl, 1996), PDH-immunoreactive neurons thatanatomically connect both accessory medullae might couple bothpacemakers. Previous cooling experiments indicated that both pacemakersare tightly coupled in cockroaches and that cooling-dependentphase shifts of one pacemaker are transferred (apparently vianeuronal connections) to the contralateral pacemaker (Page, 1981).The neuronal equivalent of this apparently direct coupling pathwayand the mechanisms of coupling remained elusive. The possibilityof a subpopulation of PDH-immunoreactive neurons being a neuronalsubstrate for the so far unknown coupling pathway is supportedfurther by lesion experiments that revealed a correlation betweenthe number of regenerating PDH-immunoreactive commissures andchanges in the period of the regained locomotor activity rhythm(Homberg and Stengl, 1994). The shortening of the period of theregained locomotor activity rhythm in animals with supernumeraryregenerated PDH-immunoreactive commissures (Stengl and Homberg,1994) agrees with previous experiments showing that both pacemakerstogether generate a shorter period of the locomotor activity rhythmcompared with a single pacemaker (Page, 1978).

The data presented in this study do not reveal whether PDH-immunoreactive neurons act only upstream of the pacemaker or whetherthey are also an integral part of the endogenous oscillator. Becausein Drosophila melanogaster PDH-immunoreactive cells contain essentialmolecular components of the pacemaker, and they seem to be necessaryfor the expression of circadian locomotor rhythms, it might bepossible that PDH-immunoreactive cells are pacemaker neurons perse in insects (Helfrich-Förster and Homberg, 1993; Hall, 1995;Helfrich-Förster, 1995, 1997; Hunter-Ensor et al., 1996). Thus,it needs to be tested whether individual PDH-immunoreactive neuronsare able to generate circadian membrane and action potential rhythms(R. Lösel, B. Petri, M. Stengl, and U. Homberg, unpublished observations),as has been shown for mollusk and vertebrate pacemaker cells (Michelet al., 1993; Welsh et al., 1995).

In conclusion, this study presents the first direct physiological evidence of the circadian function of the neuropeptide PDH.This as well as several other lines of evidence suggest that PDH-immunoreactiveneurons with their primary arborization area in the AMe are anonphotic input into the clock and/or circadian pacemakers perse in the cockroach L. maderae.

FOOTNOTES

Received Jan. 6, 1997; revised March 10, 1997; accepted March 19, 1997.

This research was supported by Deutsche Forschungsgemeinschaft Grants Ste 531/1-1, Ho 950/9-1, and Ste 531/7-1. We are gratefulto Dr. K. R. Rao for the generous supply of PDH peptides and Dr.T. Roenneberg for the Chrono II software. Furthermore, we thankG. Stoeckl, R. Zintl, and S. Gries for technical support and Drs.Uwe Homberg and J. Kien for critical reading of this manuscript.

Correspondence should be addressed to Dr. Monika Stengl at the above address.

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