Modular Organization of Turtle Spinal Interneurons during Normal and Deletion Fictive Rostral Scratching

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The Journal of Neuroscience, August 1, 2002, 22(15):6800-6809

Modular Organization of Turtle Spinal Interneurons during Normal and Deletion Fictive Rostral Scratching
Paul S. G. Stein and Susan Daniels-McQueen
Department of Biology, Washington University, St. Louis, Missouri 63130

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

During normal rostral scratching in the spinal turtle, there is rhythmic alternation between hip-flexor and hip-extensor motoractivity. During rostral scratching with hip-extensor deletions,there are successive bursts of hip-flexor motor activity and noactivity in hip-extensor motor neurons. We characterized the ON-and OFF-phases of 72 descending propriospinal interneurons withdistinct activity bursts during normal rostral scratching. Wealso studied the activity of these interneurons during deletionscratching. Hip-extensor interneurons were active when hip-flexormotor neurons were quiet in normal scratching and had zero overlapwith hip-flexor motor activity. This population of hip-extensorinterneurons, termed the hip-extensor module or hip-extensor unit-burstgenerator, was mainly quiet during deletion scratching. Our observationsupports the concept that a module is a neuronal population thatmay be active or quiet in a coordinated manner during a spinalmotor rhythm. During normal scratching, hip-flexor interneuronswere active during hip-flexor motor activity, and spanning interneuronswere active during both hip-flexor motor activity and quiescence.Hip-flexor and spanning interneurons with intermediate overlapwith hip-flexor motor activity fired in bursts during deletionscratching. Hip-flexor and spanning interneurons with large overlapwith hip-flexor motor activity fired continuously during deletionscratching. Key features of hip-flexor and spanning interneuronfiring during normal scratching were preserved during deletionscratching. Thus these features do not require activity in thehip-extensor module in every cycle of a motorrhythm.

Key words: spinal cord; scratch reflex; half-center; central pattern generator; turtle; reciprocal inhibition; fictive motor patterns

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Rhythmic alternation between hip flexors and hip extensors is a fundamental feature of many motor behaviors of the vertebratehindlimb (Stein and Smith, 1997). A major goal of spinal cordresearch is characterization of interneuronal populations responsiblefor rhythm generation in hindlimb motor neurons (Stein et al.,1997). Several hypotheses of spinal cord organization postulatespecific interneuronal populations that fire in a coordinatedmanner; each population contains neurons active during specificphases of the cycle. The hypotheses differ according to the specificcomposition of each population. Half-center hypotheses of hindlimbrhythm generation postulate a set of interneuronal populationsthat are each related to a single function at all joints of ahindlimb, e.g., the extensor half-center related to hip, knee,and ankle extension (Brown, 1911, 1914; Jankowska et al., 1967;Lundberg, 1981). Half-center hypotheses can explain "conventional"synergies in which all extensors are active at the same time;they do not explain "mixed" synergies in which hip extensors andknee extensors are active at different times, e.g., paw shakein cat (Stein and Smith, 1997). Modular hypotheses (Jordan, 1991)of hindlimb rhythm generation postulate a set of interneuronalpopulations that are each related to a single function at a singlejoint, e.g., hip-extensor module or hip-extensor unit-burst generator(Grillner, 1981; Stein et al., 1995, 1998a,b; Currie and Gonsalves,1997, 1999). Modular hypothesis have the ability to explain bothconventional and mixed synergies. Analyses of interneuronal populationsduring variations in motor rhythms with mixed synergies allowfurther examinations of these hypotheses. Half-center hypothesespredict that all extensor half-center interneurons will displaysimilar responses during a mixed-synergy variation. Modular hypothesespredict that hip-extensor interneurons will display differentresponses than knee-extensor interneurons during a mixed-synergyvariation.

The motor rhythms of rostral scratching in the turtle display a mixed synergy (Stein and Grossman, 1980; Robertson et al.,1985; Robertson and Stein, 1988; Stein et al., 1995, 1998a,b;Earhart and Stein, 2000a,b) and allow examination of these predictions.Rhythmic alternation between hip-flexor and hip-extensor motoractivity occurs during normal rostral scratching. During rostralscratching with hip-extensor deletions, a spontaneously occurringvariation, there are rhythmic bursts of hip-flexor motor activityand no hip-extensor motor activity. During both types of rostralscratching, knee-extensor motor neurons are active during thelatter portion of hip flexor activity. Recordings of synapticpotentials in turtle motor neurons during both types of rostralscratching support the concept that hip-extensor interneuronsbelong to a different population than knee-extensor interneurons(Robertson and Stein, 1988).

Berkowitz and Stein (1994a,b) characterized the activity patterns of descending propriospinal interneurons during normal scratchingusing single-unit recordings from descending axons at the posteriorcut face of the turtle spinal cord (Currie and Stein, 1990). Weuse this technique to characterize unit activity of descendingpropriospinal interneurons with axons in the turtle dorsolateralfuniculus that fire in bursts during normal rostral scratching.We also study these interneurons during rostral scratching withhip-extensordeletions.

Our data support modular hypotheses and have been presented previously in an abstract (Stein and Daniels-McQueen, 2001).

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Surgical preparation. Red-eared turtles (n = 20; Candy's Quality Reptiles, La Place, LA; William A. Lemberger Company, Oshkosh,WI; and Charles D. Sullivan Company, Nashville, TN), Trachemysscripta elegans (formerly Pseudemys scripta elegans), weighing500-850 gm, were placed on crushed ice at least 1 hr before surgeryto induce hypothermic analgesia (Melby and Altman, 1974). Eachturtle was then spinalized just caudal to the forelimb enlargementby complete spinal transection midway between the D2 and D3 dorsalroots (see Fig. 1). After spinal transection, the cord was coveredwith Gelfoam surgical sponges (Upjohn, Kalamazoo, MI) soaked inturtle saline (Stein and Schild, 1989), and the opening was sealedwith a wax plug glued to theshell.

The spinal cord was exposed from the D7 segment to the D10 segment so that the dorsal roots of segments D7-D10 could be visualized(Mortin and Stein, 1990). At the posterior end of the D10 segment,the spinal cord was completely transected (see Fig. 1). This preparationwith two spinal transections is termed the D3-D10 preparation(Mortin and Stein, 1989). The spinal cord, from the D7 segmentto the D10 dorsal roots, was covered with Gelfoam soaked withturtle saline. The remainder of the exposed spinal cord, includingthe posterior cut face of the D10 segment, was covered with turtlesaline. We visualized the boundary of the gray matter and thewhite lateral funiculus in the unstained cut face of the D10 segmentof the spinalcord.

The right hip flexor nerve VP-HP that innervates puboischiofemoralis internus, pars anteroventralis muscle (Walker, 1973;Robertson et al., 1985) was dissected in all preparations forrecordings of electroneurograms (ENGs) and is labeled HIP FLEXORin Figures 1-7. In each preparation, one or more of the followingright nerves were also dissected for ENG recordings: the rightbiarticular knee extensor nerve AM-KE that innervates tricepsfemoris, pars ambiens (labeled KNEE EXTENSOR in Figs. 1, 2, 4-7);the right monoarticular knee extensor nerve FT-KE that innervatestriceps femoris, pars femorotibialis (data not shown); and theright hip extensor nerve HR-KF that innervates the flexor cruris,pars flexor tibialis internus muscle and several other musclesthat extend the hip and flex the knee (labeled HIP EXTENSOR inFigs. 1, 2). The turtle remained on crushed ice throughout allof the above surgicalprocedures.

After the above procedures were completed, the turtle was removed from the crushed ice, allowed to warm up to room temperature,and immobilized with gallamine (Flaxedil; Rhone-Poulenc RorerCanada, Montreal, Canada), a neuromuscular blocking agent, ata dosage of 8 mg/kg body weight. Dental wax (Modern MaterialsRed Utility Wax Strips, Miles, South Bend, IN) was molded intowells to surround each of the surgically exposed regions; thewells were glued to the shell with Permabond 910 adhesive (Permabond,Englewood, NJ). The peripheral-nerve well was filled with mineraloil. The well around the D7-D10 spinal-cord exposure was filledwith saline. The trachea was intubated, and the turtle maintainedon artificial respiration for the remainder of theexperiment.

Recordings. ENGs from each right nerve were obtained using a pair of silver wire electrodes 100 µm in diameter that were immersedin the mineral-oil pool (Robertson et al., 1985). The ENGs wereamplified and filtered (0.1-1 kHz bandpass). Single-unit recordingsof action potentials of descending propriospinal interneuronsin the right dorsolateral funiculus at the posterior cut faceof the D10 segment were obtained using a microsuction electrodewith an inner diameter of 5-15 µm (Currie and Stein, 1990; Berkowitzand Stein, 1994a,b). The dorsolateral funiculus was defined asthe region of the lateral funiculus dorsal to the central graycommissure. The unit extracellular action potentials were amplifiedand filtered (0.3-3 kHz bandpass). The ENGs and unit action potentialswere stored on digital audio tape (DC-5 kHz bandpass) for lateranalyses and hard-copyprintouts.

Stimulation. Fictive rostral scratch motor patterns were elicited by mechanical stimulation of specific sites in the rightand left rostral-scratch receptive fields [see Mortin and Stein(1990) for a description of stimulation sites]. Mechanical stimulationwas applied by using the smooth, fire-polished end of a glassrod. All of the scratch motor patterns in the present study were"fictive," that is, they were obtained in the immobilized preparationin the absence of movement; when "scratching" is described inthe remainder of this paper, it refers to fictive scratching.We allowed a 2-4 min recovery between stimulus presentations.In most episodes, only unilateral stimulation of a site in theright rostral-scratch receptive field was used. In other episodes,simultaneous bilateral stimulation of mirror-image sites in theleft and right rostral-scratch receptive fields was used (Steinet al., 1995, 1998a,b; Currie and Gonsalves, 1997, 1999).

Rostral scratching motor patterns. The normal motor pattern of rostral scratching (see Fig. 2A) includes rhythmic alternationbetween hip-flexor activation and quiescence (Robertson et al.,1985). During rostral scratching with hip-extensor deletions (seeFig. 2B), hip-flexor activation occurs in bursts with no quiescencebetween bursts (Robertson and Stein, 1988; Stein et al., 1995,1998a,b).

For quantitative analyses of rostral scratch motor patterns, we digitized hip flexor ENGs at 2 kHz using Cambridge ElectronicDesign 1401plus hardware with SPIKE 2 software (Windows version3.18, Cambridge, UK). The absolute value of the difference betweeneach of the 2000 voltage measurements per second and the meanvoltage for that channel was obtained ("full-wave rectification");the mean of 20 successive full-wave rectified measurements wascalculated ("integrated") so that there were 100 integrated full-waverectified data points per second (see Fig. 3). For each integratedfull-wave rectified hip-flexor ENG, we measured the "baselineamplitude" of the quiescent ENG (maximum value minus minimum value)before the onset of stimulation. We defined the threshold of thehip flexor ENG burst as the sum of the value of the baseline amplitudeplus the value of maximum ENG during quiescence, i.e., the threshold/noisevalue was set at 2:1.

We used custom software written by Dr. Gavin Perry (Washington University, St. Louis, MO) to determine the onset and offsetof each hip flexor burst of integrated full-wave rectified ENGactivity (Stein et al., 1995). We analyzed burst onsets and offsetsduring normal cycles of hip-flexor activity that displayed rhythmicalternation between hip-flexor activity and quiescence. Each cycleof normal rostral scratching had a period of hip-flexor quiescencethat remained below hip-flexor ENG threshold for $>=$ 50 msec, i.e.,there were at least five successive integrated full-wave rectifieddata points during the hip flexor quiescence of a normal scratchcycle. We also analyzed hip-flexor burst onsets and offsets duringhip-extensor deletions. Each cycle of deletion rostral scratchinghad at most four successive data points (40 msec) that remainedbelowthreshold.

Single-unit recognition and analyses. For quantitative analyses of interneuronal firing patterns we digitized microsuction-electroderecordings at 20 kHz using Cambridge Electronic Design hardwareand software. We recognized single units (n = 72) with Spike 2template matching software. For most interneuronal recordings,we studied only the most prominent unit; in a few cases, we discriminatedbetween and studied the two most prominent units. During normalscratching, we identified the onset and offset of each unit'sburst of two or more action potentials and measured instantaneousfrequency (1/interspike interval) during eachburst.

During each cycle of normal scratching, we used double-referent phase measurement techniques to calculate the phase of theonset ("ON-phase") and the phase of the offset ("OFF-phase") ofeach unit's burst (Berkowitz and Stein, 1994b). Normal scratchingcycles in which the unit had zero or one action potential werenot included in the phase calculation. For each unit in the study,we measured ON- and OFF-phases of bursts during at least 10 cyclesof normal scratching. We defined the start of each hip-flexorburst as the 0.0 and 1.0 phases and the end of each hip-flexorburst as the 0.5 phase. The phase of an event occurring duringhip-flexor activity was defined as the latency of the event fromhip-flexor onset divided by twice the duration of the hip-flexorburst (see Fig. 3). The phase of an event occurring during hip-flexorquiescence was defined as 0.5 plus the latency of the event fromhip-flexor offset divided by twice the duration of hip-flexorquiescence (see Fig. 3). We used vector averaging techniques appropriatefor circular data (Batschelet, 1981; Berkowitz and Stein, 1994b)to calculate the mean phase and angular deviation of the ON- andOFF-phases of each unit. Angular deviation for circular data issimilar to SD for linear data (Batschelet, 1981). We applied theRayleigh Test (Batschelet, 1981) to determine whether the distributionof ON- and OFF-phases for each unit was significantly differentfrom a randomdistribution.

During normal scratching, we used unit mean ON- and OFF-phases to calculate the overlap of each unit's firing with hip-flexoractivity (see Fig. 3). Overlap percentage was defined as the percentageof hip-flexor activity during which the unit was active. Unitswith 0% overlap had mean ON- and OFF-phases during hip-flexorquiescence.

During each cycle of deletion scratching, we recognized four unit firing categories: quiescence, single spike, burst of twoor more spikes, and continuous firing. For each unit in the study,we characterized at least two cycles of deletion scratching. For70 of 72 units, we defined continuous firing as instantaneousfrequency >5 Hz for an entire cycle. We needed to modify thiscriterion for two units that fired with low frequency. For thesetwo units, we measured the minimum instantaneous frequency duringeach cycle of normal scratching: critical frequency for each unitwas defined as the largest of these minima, and unit behaviorwas defined as continuous during a cycle of deletion scratchingif instantaneous frequency always exceeded criticalfrequency.

For units with 0% overlap, we counted the number of action potentials during each cycle of normal scratching and during eachcycle of deletion scratching. For both types of scratching, weincluded cycles with unit quiescence, single spike, or burst oftwo or more action potentials. For each unit, we used the one-tailedMann-Whitney U test (Siegel, 1956) to calculate the statisticalsignificance between the number of action potentials in each cycleof normal scratching compared with the number of action potentialsin each cycle of deletionscratching.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Fictive rostral scratching motor patterns

We studied two types of fictive rostral scratching (Robertson et al., 1985; Robertson and Stein, 1988), normal (see Fig. 2A)and with hip-extensor deletions (see Fig. 2B), in the D3-D10 preparationof the turtle spinal cord (Fig. 1) (Mortin and Stein, 1989). Thiseight-segment preparation contained the midbody spinal segments(D3-D6), the dermatomes of which included the rostral-scratchreceptive field (Mortin and Stein, 1990), and the first threespinal segments (D8-D10) of the five-segment hindlimb enlargement(Ruigrok and Crowe, 1984). The D8-D10 segments contain the somataof all the hip-flexor motor neurons, all the knee-extensor motorneurons, and some of the hip-extensor motor neurons (Ruigrok andCrowe, 1984).

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Figure 1. Sketch of the D3-D10 preparation. The spinal cord was completely transected in two locations: at the border of the D2 and D3 spinal segments just posterior to the forelimb enlargement and at the border of the D10 and S1 spinal segments within the hindlimb enlargement. ENG recordings were obtained from hip-flexor, knee-extensor, and hip-extensor motor nerves. Single-unit recordings from descending propriospinal interneurons were obtained from the cut ends of axons in the dorsolateral funiculus at the posterior face of the D10 spinal segment. Fictive rostral scratching was evoked by mechanical stimulation of the rostral-scratch receptive field located on the shell bridge in the midbody region of the turtle.

On some occasions, tactile stimulation in the rostral scratch receptive field elicited the normal pattern of fictive rostralscratching: there was rhythmic alternation between hip-flexormotor activity and quiescence (Fig. 2A). Hip-extensor motor activityoccurred during hip-flexor quiescence. The hip-flexor burst duringa rostral scratch had a characteristic shape: it began with low-levelactivity, gradually reached maximum activity, and then rapidlydeclined near the end of the burst. Knee-extensor motor activityoccurred during the latter portion of hip-flexor activity.

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Figure 2. A, B, ENG recordings from right knee-extensor (top trace), right hip-flexor (middle trace), and right hip-extensor (bottom trace) motor nerves during fictive rostral scratching. A, Normal rostral scratching with rhythmic alternation between hip-flexor activity and quiescence elicited by mechanical stimulation of the right rostral-scratch receptive field at SP1. Hip-extensor activity occurred during hip-flexor quiescence. B, One cycle of rostral scratching with a hip-extensor deletion (end of cycle marked with $black-diamond$ ). At the $black-diamond$ there was no hip-extensor activity and no quiescent period between the end of the hip flexor burst and the start of the next hip flexor burst. The other cycles exhibited normal rostral scratching. The episode was elicited by mechanical stimulation of the right rostral-scratch receptive field at SP2.5 [see Mortin and Stein (1990) for descriptions of locations on the turtle shell].

During other occasions, tactile stimulation in the rostral scratch receptive field elicited rostral scratching with hip-extensordeletions: there was no hip-flexor quiescence and no hip-extensoractivity (Fig. 2B, end of deletion cycle marked with $black-diamond$ ). Duringthis variation of rostral scratching, the decline of hip-flexoramplitude at the end of one hip-flexor burst was followed immediatelyby the rise of hip-flexor amplitude at the beginning of the subsequenthip-flexor burst. There was a burst of knee-extensor activityin the latter portion of each hip-flexorburst.

Unit recordings of descending propriospinal interneurons

We recorded the unit activity of interneurons with axons that descended in the right dorsolateral funiculus at the posteriorend of the D10 spinal segment (Fig. 1). These units were interneurons;there are no axons of sensory or motor neurons in the dorsolateralfuniculus of the turtle (Currie and Stein, 1990; Berkowitz andStein, 1994a,b,c). These units were descending propriospinal interneurons.We recorded from the cut ends of descending axons at the posteriorface of an eight-segment chain of spinalcord.

We studied 72 interneurons that fired in distinct bursts of two or more action potentials during 2105 cycles of normal rostralscratching. For each cycle of normal scratching for each unit,we measured the double-referent ON- and OFF-phases of each burstwith respect to the hip-flexor motor-neuron activity cycle (Fig.3). We calculated the mean ON- and OFF-phases for each unit duringnormal scratching. We used these mean phase values to determinethe overlap of each unit with respect to hip-flexor activity duringnormal rostral scratching (Fig. 3). We categorized interneuronsaccording to their overlap. Some interneurons had 0% overlap.For these interneurons, the mean ON- and OFF-phases occurred exclusivelyduring hip-flexor quiescence (Fig. 4); we term these hip-extensorinterneurons (see also Discussion, Axonal recordings). Other interneuronshad overlap. Some of these fired exclusively during hip-flexoractivity (Fig. 5); we term these hip-flexor interneurons. Othersfired during both hip-flexor activity and quiescence (Figs. 6,7); we term these spanning interneurons. We represented the meanON- and OFF-phases for the 72 units in the study during normalcycles of rostral scratching by the beginnings and ends, respectively,of the bars in Figure 8. The distributions of each of the 72 ON-phasesand 70 of the 72 OFF-phases were significantly different fromrandom at the p < 0.001 level (Rayleigh Test) (Batschelet, 1981).Two of the OFF-phases were significantly different at the p <0.01 level.

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Figure 3. Sketch of technique used to measure double-referent phase of single-unit interneuron (bottom trace) activity during normal rostral scratching with respect to the hip-flexor ENG burst (middle trace) and the integrated full-wave rectified hip-flexor ENG (top trace). The start of the burst of the integrated full-wave rectified hip-flexor ENG was defined as 0.0 (and 1.0) phase; the end of the burst was defined as 0.5 phase. In this example, the start of the unit burst occurred when hip-flexor activity was 74% complete. This ON-phase occurred at 0.37 (= 0.74/2). The end of the unit burst occurred when hip-flexor quiescence was 54% complete. This occurred at an OFF-phase of 0.77 [= 0.5 + (0.54/2)]). See Materials and Methods for details of double-referent phase calculation (Berkowitz and Stein, 1994b). The unit was active during 26% of the hip-flexor burst; in this example of a single cycle shown for illustration, we term this 26% overlap. In the remainder of the paper, overlap percentage was calculated on the basis of mean ON- and OFF-phases for each unit.

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Figure 4. Hip-extensor interneuron with 0% overlap was active in a burst during hip-flexor quiescence of normal rostral scratching and was quiet during rostral scratching with a hip-extensor deletion. A, Recordings of knee-extensor motor nerve (top trace), hip-flexor motor nerve (second trace), instantaneous frequency of unit (third trace), and interneuron unit activity (bottom trace) during rostral scratching elicited by mechanical stimulation of SP1 in the right rostral-scratch receptive field. The first cycle is an example of rostral scratching with a hip-extensor deletion (end of cycle marked with $black-diamond$ ). The other cycles are examples of normal rostral scratching. B, Start and end of bar represent mean ON-phase of 0.58 (±0.06 angular deviation; p < 0.001; Rayleigh Test) and mean OFF-phase of 0.82 (±0.05 angular deviation; p < 0.001; Rayleigh Test) of unit firing during 57 cycles of normal rostral scratching. Bar is unfilled to represent unit quiescence during all nine cycles of deletion rostral scratching.

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Figure 5. Hip-flexor interneuron with 46% overlap was active in a burst during normal and deletion rostral scratching. During normal scratching, the burst of the unit occurred during a portion of the hip-flexor motor activity. A, Labeling of traces as in Figure 4. Rostral scratching was elicited by mechanical stimulation of SP1 on the right side. The first three cycles are examples of rostral scratching with hip-extensor deletions (ends of cycles marked with $black-diamond$ ). The remaining cycles are examples of normal rostral scratching. B, Start and end of bar represent mean ON-phase of 0.19 (±0.07 angular deviation; p < 0.001; Rayleigh Test) and mean OFF-phase of 0.42 (±0.05 angular deviation; p < 0.001; Rayleigh Test) of unit firing during 34 cycles of normal rostral scratching. Bar is gray-filled to represent unit bursting during all 13 cycles of deletion rostral scratching.

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Figure 6. Spanning interneuron with 48% overlap was active in a burst during normal and deletion rostral scratching. During normal scratching, the burst of the unit occurred during the latter portion of hip-flexor activity and during the early portion of hip-flexor quiescence. During deletion scratching, the burst of the unit occurred during the latter portion of hip-flexor activity. A, Labeling of traces as in Figure 4. Rostral scratching was elicited by simultaneous mechanical stimulation of SP2 on the left and right sides. The first two cycles are examples of rostral scratching with hip-extensor deletions (ends of cycles marked with $black-diamond$ ). The remaining cycles are examples of normal rostral scratching. B, Start and end of bar represent mean ON-phase of 0.26 (±0.06 angular deviation; p < 0.001; Rayleigh Test) and mean OFF-phase of 0.83 (±0.09 angular deviation; p < 0.001; Rayleigh Test) of unit firing during 21 cycles of normal rostral scratching. Bar is gray-filled to represent unit bursting during all 10 cycles of deletion rostral scratching.

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Figure 7. Spanning interneuron with 98% overlap was active in a frequency-modulated burst during normal rostral scratching and fired continuously with frequency modulation during rostral scratching with hip-extensor deletions. A, Labeling of traces as in Figure 4. Rostral scratching was elicited by mechanical stimulation of SP3 on the right side. The third and fourth cycles are examples of rostral scratching with hip-extensor deletions (ends of cycles marked with $black-diamond$ ). The first and second cycles are examples of normal rostral scratching. B, Start and end of bar represent mean ON-phase of 0.01 (±0.01 angular deviation; p < 0.001; Rayleigh Test) and a mean OFF-phase of 0.51 (±0.02 angular deviation; p < 0.001; Rayleigh Test) of unit firing during 35 cycles of normal rostral scratching. Bar is black-filled to represent continuous firing of the unit during all five cycles of rostral scratching with hip-extensor deletions.

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Figure 8. Double-referent mean ON- and OFF-phases (± angular deviation) of 72 descending propriospinal interneurons during normal rostral scratching represented by the start and end, respectively, of each bar. Unit firing during rostral scratching with hip-extensor deletions is indicated by the fill of each bar: unfilled bar for quiescence; gray-filled bar for a burst; black-filled bar for continuous firing. Nearly all units with 0% overlap with hip-flexor activity and with mean ON- and OFF-phases during hip-flexor quiescence of normal rostral scratching were quiet during deletion rostral scratching.

We also examined the firing characteristics of each of the 72 units during 495 deletion cycles with no hip-flexor quiescence,i.e., during rostral scratching with hip-extensor deletions. InFigures 2B, 4A, 5A, 6A, and 7A, the ends of these cycles are markedwith $black-diamond$ . We recognized four unit-firing categories during deletioncycles: quiescence, single spike (data not shown), burst, andcontinuous. For each unit, we determined which category was observedmost often during deletions. We represented that category by thefill of mean ON-/OFF-phase bar of that unit (Figs. 4B, 5B, 6B,7B, and 8). Units that were quiet during deletions were representedby an unfilled bar (Figs. 4B, 8). Units that fired in a burstduring deletions were represented by a gray-filled bar (Figs.5B, 6B, 8). Units that fired continuously during deletions wererepresented by a black-filled bar (Figs. 7B, 8).

Hip-extensor interneurons with 0% overlap in normal cycles were quiet during deletion cycles
An example of a hip-extensor interneuron with activity bursts that had 0% overlap with hip-flexor bursts is shown in Figure4A. All but the first cycle were normal cycles with rhythmic alternationbetween hip-flexor activity and quiescence. The first cycle (endmarked with $black-diamond$ ) was a deletion cycle with no hip-flexor quiescence.The hip-extensor interneuron fired a robust burst of activityduring hip-flexor quiescence of normal cycles. The interneuronwas quiet during the deletioncycle.
We studied a total of 19 hip-extensor interneurons during 659 cycles of normal rostral scratching. During each of these cycles,the unit was active with a burst of two or more spikes. The meanON- and OFF-phase bars for these units in Figure 8 were locatedbetween the phases of 0.50 (onset of hip-flexor quiescence) and1.00 (onset of hip-flexor burst). We recorded from these 19 unitsduring 172 deletion cycles. In 89.5% of these cycles, the unitwas quiet. In 4.1% of these cycles, the unit fired a single spike.In 6.4% of these cycles, the unit fired a burst of two or morespikes. These percentages are plotted in the 0% overlap bar inthe bottom of Figure 9. For 18 of these interneurons, the usualfiring category during deletions was quiescence. The phase barsof these units in Figure 8 were unfilled to represent this characteristic.

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Figure 9. Interneuron firing behavior during deletion cycles related to overlap during normal cycles. Unit overlap with hip-flexor activity during normal cycles was divided into six groups: 0, 1-20, 21-40, 41-60, 61-80, and 81-100%. Each group is represented by a bar. For units in each category, the percentage of deletion cycles is represented by the fill of a portion of each bar: unfilled portion for quiescence; light-gray-filled portion for single spike; medium-gray-filled portion for burst; black-filled portion for continuous.

We counted the number of action potentials in each cycle for each of the 19 hip-extensor interneurons. For normal scratching,we included 659 cycles with unit bursts of two or more actionpotentials, 34 additional cycles with one action potential, and86 additional cycles with no action potentials. For each unit,we used the one-tailed Mann-Whitney U test (Siegel, 1956) to determinethe significance of the number of action potentials during eachcycle of normal scratching compared with the number of actionpotentials during each cycle of deletion scratching. For 18 of19 units, the number of action potentials during each cycle ofnormal scratching was significantly greater than the number ofaction potentials during each cycle of deletion scratching (12units: p < 0.001; 5 units: p < 0.01; 1 unit: p < 0.05). Duringnormal scratching, these 18 units fired 9465 action potentialsduring 767 cycles with a mean of 12.34 action potentials per cycle.During deletion scratching, these 18 units fired 24 action potentialsduring 167 cycles with a mean of 0.14 action potentials per cycle.Thus, in this group of 18 units, the number of action potentialsper cycle during deletion scratching was 1.16% of the number ofaction potentials per cycle during normal scratching. This groupof 18 units was mainly quiet during deletionscratching.
For one unit, there was no significant difference between the number of action potentials in each cycle of normal scratchingcompared with deletion scratching. The value of ON-phase (0.50)minus angular deviation (0.08) of this unit was 0.42. Thus, forsome normal cycles, a portion of the firing of this unit overlappedwith the hip-flexor burst. This unit was the only unit in ourstudy with 0% overlap that usually burst during deletion cycles.Because the behavior of this unit was significantly differentfrom that of the other 18 units with 0% overlap, it is likelythat this interneuron was not a member of the same populationas that of the other 18units.
These observations of the 18 units with 0% overlap support the concept that the hip-extensor interneuron population actedas a group. During the hip-extensor phase of normal rostral scratching,each member of this population fired in a burst; during rostralscratching with hip-extensor deletions, the population was mainlyquiet. The quiescence of hip-extensor interneurons during deletionscratching corresponds to the lack of EPSPs in hip-extensor motorneurons and the lack of IPSPs in hip-flexor motor neurons duringdeletion scratching (Robertson and Stein, 1988).
Knee-extensor motor neurons receive EPSPs during deletion scratching (Robertson and Stein, 1988). Therefore knee-extensorinterneurons that synaptically excite these motor neurons areactive during deletion scratching. It follows that hip-extensorinterneurons and knee-extensor interneurons have different firingcharacteristics during rostral scratching. This supports the conceptthat the 18 hip-extensor interneurons recorded in the presentstudy are members of a hip-extensor module (Grillner, 1981; Steinet al., 1995, 1998a,b).

Interneurons with intermediate overlap (21-60%) in normal cycles fired in bursts during deletion cycles
An example of a hip-flexor interneuron with intermediate overlap with hip-flexor activity during normal rostral scratchingis shown in Figure 5A. The unit was active only during a portionof hip-flexor activity and was quiet during hip-flexor quiescence.The first three cycles were hip-extensor deletion cycles (endsmarked with $black-diamond$ ); the remaining cycles were normal cycles. In bothnormal and deleted cycles, the hip-flexor interneuron fired witha robust burst during each burst of hip-flexoractivity.
An example of a spanning interneuron with intermediate overlap with hip-flexor activity during normal rostral scratching isshown in Figure 6A. The unit was active during a portion of hip-flexoractivity and a portion of hip-flexor quiescence. The first twocycles were hip-extensor deletion cycles (ends marked with $black-diamond$ );the remaining cycles were normal cycles. In both normal and deletedcycles, the spanning interneuron fired with a robust burst. Inthe normal cycles, the burst of the unit began near the middleof the hip-flexor burst and ended near the middle of hip-flexorquiescence. In deleted cycles, the burst of the unit occurredin the latter portion of the hip-flexor motorburst.
We studied a total of nine interneurons with 41-60% overlap with hip flexor bursts during 295 cycles of normal rostral scratching.For each of the nine units, the dominant firing characteristicduring deletions was bursting. The phase bars of these units weregray-filled in Figure 8 to represent this characteristic. We recordedfrom these nine units during 66 deletion cycles. In 56 of thesecycles (84.8%), the unit fired a burst. In eight of these cycles(12.1%), the unit fired continuously. In one cycle (1.5%), theunit fired a single spike; in one cycle (1.5%), the unit was quiet.These percentages are plotted in the 41-60% overlap bar in Figure9.
Interneurons with 21-40% overlap displayed similar behavior during deletion cycles. We studied 11 units in this overlap rangeduring 320 normal cycles. For each of the 11 units, the dominantfiring characteristic during deletions was bursting; the phasebars of these units were gray-filled in Figure 8 to representthis characteristic. We recorded from these 11 units during 50deletion cycles. In 90% of these cycles, the unit fired a burst.In 8% of these cycles, the unit fired a single spike. In 2% ofthese cycles, the unit was quiet. These percentages are plottedin the 21-40% overlap bar in Figure 9.
Interneurons with 21-60% overlap with hip-flexor motor activity during normal scratching are quiet during some portion ofthe hip-flexor burst. The observation that these units burst duringdeletion cycles, that is, are quiet during some portion of thehip-flexor burst in a deleted cycle, supports the concept thatcertain characteristics of unit firing during the hip-flexor burstpresent during normal scratching were preserved during deletionscratching. These preserved features during deletion scratchingare therefore not dependent on the activity of neurons in thehip-extensormodule.
We termed interneurons with intermediate (21-60%) overlap as hip-flexor interneurons if they fired exclusively during hip-flexormotor activity (Fig. 5) and as spanning interneurons if they firedduring both hip-flexor motor activity and quiescence (Fig. 6).This classification does not address the issue of their synapticoutput. Of the interneurons with intermediate overlap, some maysynapse on hip motor neurons, others may synapse on knee motorneurons, some may synapse on both types of motor neurons, andothers synapse on neither type of motor neuron. During the latterportion of hip-flexor motor activity during both normal and deletionrostral scratching, knee-extensor motor neurons receive EPSPs(Robertson and Stein, 1988), and some interneurons with intermediateoverlap (Fig. 8) are active. We suggest that a subset of intermediate-overlapinterneurons may also be knee-extensor interneurons that synapticallyexcite knee-extensor motor neurons. This is consistent with theidea that the population of knee-extensor interneurons (that firein bursts during normal and deletion rostral scratching) are differentfrom the population of hip-extensor interneurons (that fire inbursts during normal scratching and are quiet during deletionscratching).

Interneurons with large overlap (81-100%) in normal cycles fired continuously during deletion cycles
An example of a spanning interneuron with large overlap with hip-flexor activity during rostral scratching is shown in Figure7A. This unit was active during most of the hip-flexor burst.The third and fourth cycles (ends marked with $black-diamond$ ) were deletioncycles with no hip-flexor quiescence; the first two cycles werenormal cycles with rhythmic alternation between hip-flexor activityand quiescence. The interneuron fired with frequency-modulatedbursts during the normal cycles. The interneuron fired continuouslywith frequency-modulated bursts during the deletioncycles.
We studied a total of nine interneurons with activity bursts that had large levels (81-100%) of overlap with hip-flexor burstsduring 236 cycles of normal rostral scratching. One unit was ahip-flexor interneuron that fired exclusively during the hip-flexorburst; the other eight units were spanning interneurons that eitherbegan or ended their activity during hip-flexor quiescence. Forall nine of these units, the usual firing characteristic duringdeletions was continuous firing. The phase bars of these unitsin Figure 8 were black-filled to represent this characteristic.We recorded from these nine units during 60 deletion cycles. In56 of these cycles (93.3%), the unit fired continuously; in fourof these cycles (6.7%), the unit fired in a burst. These percentagesare plotted in the top bar of Figure 9.
Interneurons with 81-100% overlap with hip flexor activity during normal scratching were active during all or nearly all ofthe hip flexor burst. The continuous activity of these interneuronsduring deletion scratching is therefore similar to the activityof these units during normal scratching. These observations supportthe concept that the basic structure of firing of large-overlapunits during the hip-flexor burst of a normal cycle is preservedduring the hip-flexor burst of a deletion cycle. These preservedfeatures during deletion scratching are therefore not dependenton the activity of neurons in the hip-extensormodule.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Timing of interneuron activity during spinal motor rhythms

We characterized the ON- and OFF-phases of a population of spinal-cord interneurons during normal fictive rostral scratchingin the turtle (Fig. 8) (Berkowitz and Stein, 1994b; Berkowitz,2001a,b). Some interneurons were active only during hip-flexormotor activity, others were active only during hip-flexor motorquiescence, and still others displayed activity during both hip-flexoractivity and quiescence. The interneuronal timings reported inturtle are similar to those reported in other limbed vertebrates:mudpuppy stepping (Wheatley et al., 1994), locomotor-like rhythmsin rabbit (Viala et al., 1991) and neonatal rat (Tresch and Kiehn,1999), cat stepping (Orlovsky and Feldman, 1972; Baev et al.,1979), and cat scratching (Berkinblit et al., 1978; Baev et al.,1981). Our findings support the hypothesis that there is a sharedset of fundamental principles underlying spinal motor rhythm generationin limbed vertebrates (Grillner, 1981; Kiehn et al., 1997; Steinand Smith, 1997; Orlovsky et al., 1999).

Axonal recordings of descending propriospinal interneurons

Our recordings are from cut axons of descending propriospinal interneurons in the right dorsolateral funiculus at the posteriorface of the third spinal segment of a five-segment hindlimb enlargement.Our findings support the concept that a collection of axons locatedon the right side of the spinal cord functions as a coordinatedpopulation. We did not identify the synaptic output of these axons.We assume that some of our recordings are from excitatory interneuronsand the remainder are from inhibitory interneurons. Most likelythese right-sided descending axons are presynaptic to right-sidedspinal interneurons and motor neurons. We found it useful to categorizethe phase of these right-sided descending axons according to thecycle times of right hip-flexor motor neurons on the basis, inpart, of the assumption that right-sided spinal neurons are postsynapticto these descendingaxons.

Some right-sided descending axons of propriospinal interneurons have ipsilateral cell bodies, and other right-sided descendingaxons have contralateral cell bodies (Berkowitz and Stein, 1994c;Eide et al., 1999). Studies using unit recordings from cell bodies(Berkowitz, 2001a,b) during normal and deletion rostral scratchingare needed to examine the modular organization of spinal neuronson the basis of the location of their cell bodies; i.e., neuronswith left-sided somata may be grouped into modules that differfrom modules with right-sidedsomata.

Hip-flexor rhythms occur even when hip-extensor interneurons are quiescent

Modular hypotheses of motor pattern generation of spinal rhythms postulate the existence of a hip-flexor module and a hip-extensormodule (Grillner, 1981; Stein et al., 1995, 1998a,b) [see Fig.9 of Stein et al. (1995)]. Reciprocal inhibition between the hip-flexormodule and the hip-extensor module is a major mechanism that contributesto rhythm generation (Grillner, 1981; Lundberg, 1981; Marder andCalabrese, 1996; Sharp et al., 1996; Calabrese and Feldman, 1997).Reciprocal inhibition between antagonist modules may not be thesole mechanism for spinal rhythm generation,however.

During rostral scratching with hip-extensor deletions in the turtle, there is rhythmic activation of hip-flexor motor neurons,and hip-extensor motor neurons are quiet. This supports the conceptthat there is an additional mechanism for rhythmogenesis: thehip-flexor module is a unit burst generator that produces a hip-flexormotor rhythm even when the antagonist hip-extensor motor neuronsare quiet (Grillner, 1981; Stein et al., 1995, 1998a,b). Underlyingthis conceptual mechanism is the assumption that interneuronsin the hip-extensor module are silent when hip-extensor motorneurons are silent. Our unit recordings from hip-extensor interneurons(Figs. 4, 8) that were quiet during rostral scratching with hip-extensordeletions provide direct support for thisassumption.

Some of the hip-extensor interneurons of the present study are likely to be inhibitory. When hip-extensor inhibitory interneuronsare silent, modular hypotheses predict a corresponding lack ofIPSPs in hip-flexor interneurons and hip-flexor motor neurons.The predicted absence of IPSPs in hip-flexor interneurons is consistentwith the concept that reciprocal inhibition between hip-flexorinterneurons and hip-extensor interneurons is not the sole mechanismfor rhythmogenesis. Future experiments with intracellular recordingsfrom hip-extensor interneurons during normal and deletion rostralscratching will provide a critical test of this prediction. Duringnormal rostral scratching, intracellular recordings from hip-flexormotor neurons demonstrate IPSPs during hip-extensor activity.During rostral scratching with hip-extensor deletions, these IPSPsin hip-flexor motor neurons are absent (Robertson and Stein, 1988).Thus our observations here with unit recordings from interneuronsare consistent with previous observations of synaptic recordingsfrom motor neurons. Both sets of observations support the conceptthat a population of interneurons, termed the hip-extensor module,functions as a group. This population is active during the hip-extensorphase of normal rostral scratching and quiet during rostral scratchingwith hip-extensordeletions.

Our observations of quiet interneurons in the hip-extensor module when hip-extensor motor neurons are quiet also support theconcept that hip-extensor excitatory interneurons are quiet duringrostral scratching with hip-extensor deletions. Modular hypothesespredict that hip-extensor excitatory interneurons excite eachother as well as hip-extensor motor neurons. During normal rostralscratching, intracellular recordings from hip-extensor motor neuronsdemonstrate EPSPs during hip-extensor motor-nerve activity. Duringrostral scratching with hip-extensor deletions, these EPSPs inhip-extensor motor neurons are absent (Robertson and Stein, 1988).A fraction of our descending propriospinal interneurons are likelyto be excitatory; therefore, our observations with unit recordingsduring deletions are consistent with observations of synapticpotentials from hip-extensor motorneurons.

Rostral scratching with hip-extensor deletions in the turtle is a model system to study spinal-cord rhythmic activation ofagonists during antagonist quiescence. Observations of agonistrhythms during antagonist quiescence have been made in other limbedvertebrates: mudpuppy stepping (Cheng et al., 1998), neonatalrat locomotor-like rhythms (Hochman and Schmidt, 1998), and catstepping (Grillner and Zangger, 1979; Jordan, 1991). Our inferencesabout the organization of the turtle spinal cord may also serveas hypotheses in studies of spinal cord in other limbedvertebrates.

Differences between a hip-extensor module and an extensor half-center

Rostral scratching in the turtle is an example of a "mixed synergy" (Stein and Smith, 1997) in which extensors at one jointfire at a different time than extensors at another joint; flexorsof one joint are coactive with extensors of another joint. Anotherexample of a mixed synergy is paw shake in cat (Smith et al.,1985; Pearson and Rossignol, 1991). In normal rostral scratchingin the turtle, hip-extensor motor neurons fire at a phase of thecycle different from knee-extensor motor neurons. Knee-extensormotor neurons are active during the latter portion of each hip-flexormotor neuron burst (Fig. 2A). In deletion cycles, hip-extensormotor neurons are quiet, and knee-extensor motor neurons are activeduring the latter portion of each hip-flexor motor neuron burst(Fig. 2B).

These differences between the motor-neuron activities of hip extensors and knee extensors during rostral scratching observedpreviously (Stein and Grossman, 1980; Robertson and Stein, 1988)are observed at the level of interneuronal recordings in the presentpaper. Interneurons active during hip-extensor motor activityof normal rostral scratching were quiet during deletion rostralscratching (Figs. 4, 8). During normal rostral scratching, interneuronsactive during knee-extensor motor activity overlap the latterportion of hip-flexor motor activity; these interneurons firein a burst during knee-extensor motor activity of rostral scratchingwith hip-extensor deletions (Figs. 5, 8). Intracellular recordingsduring rostral scratching with hip-extensor deletions demonstratebursts of EPSPs in knee-extensor motor neurons during the latterportion of each hip-flexor burst (Robertson and Stein, 1988).These EPSPs are likely driven by knee-extensor excitatory interneuronsactive during deletion scratching. Interneurons active duringknee-extensor activity belong to a different population than interneuronsactive during hip-extensor activity. Interneurons of the hip-extensormodule are different from interneurons related to knee-extensormotor activity. This conflicts with the hypothesis that interneuronsin an extensor half-center are related to extensor motor activityat all the joints of a limb. For the mixed synergy of rostralscratching in turtle, our data support the concept of a hip-extensormodule and reject the concept of an extensor half-center. Thehalf-center concept can be tested in the spinal cords of othervertebrates that generate mixed synergies, e.g., during the pawshake in the cat (Smith et al., 1985; Pearson and Rossignol, 1991).Our work with a mixed-synergy rhythm in turtle supports the predictionthat the half-center concept cannot account for the full repertoireof rhythmic motor output in limbedvertebrates.

Whether interneurons related to knee-extensor activity belong to a knee-extensor module remains an open issue. Grillner (1981)postulated a distinct knee-extensor module. Robertson et al. (1985)support the utility of the concept. In contrast, Robertson andStein (1988) and Berkowitz and Stein (1994b) failed to find strongevidence for the knee-extensor module concept. In future work,we will examine correlations between propriospinal-interneuronactivity and knee-extensor activity to determine whether the activityof a subpopulation of interneurons is strongly related to knee-extensormotoractivity.

  FOOTNOTES

Received Jan. 31, 2002; revised May 9, 2002; accepted May 15, 2002.

This work was supported by National Institutes of Health Grant NS30786 to P.S.G.S. We thank Dr. Gavin Perry for software developmentand Drs. Ari Berkowitz and Gammon Earhart for editorialcomments.

Correspondence should be addressed to Dr. Paul S. G. Stein, Department of Biology, Washington University, St. Louis, MO 63130.E-mail: stein{at}biology.wustl.edu.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
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