Synaptic specificity in the first instar cockroach: patterns of monosynaptic input from filiform hair afferents to giant interneurons

Summary Direct evidence for monosynaptic connections between filiform hair sensory axons and giant interneurons (GIs) in the first instar cockroach, Periplaneta americana, was obtained using intracellular recording and HRP injection followed by electron microscopy. GIs 1–6 all receive monosynaptic input from at least one filiform afferent axon. GI1, GI2 and GI5 receive input only from the medial (M) axon, while GI3, GI4 and GI6 receive input from both M and lateral (L) axons. The dendrites of GI3 and GI6 which are contralateral to the cell bodies receive input from both axons whereas the smaller ipsilateral dendritic fields have synapses only from the L axon. GI5 has M axon input only onto its contralateral dendrites. In 50% of preparations GI7 receives weak input from the ipsilateral L axon. There is no obvious relationship between the morphology of the giant interneurons and the pattern of input they receive from the filiform afferents.Abbreviations GI giant interneuron - HRP horseradish peroxidase - L lateral axon - M medial axon     

The role of afferent activity in behavioral and neuronal plasticity in an insect

Summary Cockroaches (Periplaneta americana) have been shown to adapt behaviorally, in about 1 month, to ablation of one cercus. Additionally, those giant interneurons (GIs) that normally receive their major input from the lesioned cercus become more responsive to stimulation of the intact side (Vardi and Camhi 1982 a, b). To investigate the role of afferent activity in the behavioral and neuronal plasticity, we silenced wind-evoked activity in the intact cercus by immobilizing the sensory hairs. This was carried out during the last nymphal stage which lasts for about one month. The animals were tested behaviorally and physiologically after they had molted to adults and a fresh set of mobile hairs had appeared. These animals showed no behavioral correction (Fig. 3). The responses of the GIs on the ablated side were somewhat enhanced, but they were also significantly smaller than those in animals with long-term cercal ablations and no sensory deprivation (Fig. 5). A variety of controls (Figs. 8, 9, and 10) were used to show that sensory deprivation by itself did not decrease the responsiveness of the afferents or the GIs. Thus elimination of wind-evoked activity specifically decreasesenhancement of the responses in the GIs.Abbreviation GI giant interneuron     

Patterns of monosynaptic input to the giant interneurons 1–3 in the cereal system of the adult cockroach

1. The cerci of the cockroach Periplaneta americana bear filiform hair mechanoreceptors that are arranged in segmentally repeated rows and longitudinal columns. The monosynaptic connections between receptors of the same column or row and the 3 largest giant interneurons (GIs) were compared using the oil-gap single fibre technique.
2. For many columns, the synaptic efficacy of the afferents decreased gradually from the base to the tip of the cercus, but columns with an inverted gradient or without any gradient were also observed. On the ipsilateral side (relative to the GI axon), the inverted gradients were exclusively found for columns with short proximal hairs. For one column (d) and GI3, the ipsilateral and contralateral gradients were opposite.
3. Monosynaptic EPSPs evoked by stimulating different receptors of the same segment (segment 3) were of very different amplitudes, which partially account for the directional sensitivity of the GIs. Differences in the location, shape and size of the afferent terminals were not sufficient to explain these differences in connection strength.
4. No correlation was found between the size of the EPSPs produced by a sensory neuron and the length of its associated hair.

     

Regeneration of cercal filiform hair sensory neurons in the first-instar cockroach restores escape behavior

Neural regeneration in the escape circuit of the first-instar cockroach is described using behavioral analysis, electrophysiology, intracellular staining, and electron microscopy. Each of the two filiform hairs on each of the animal's cerci is innervated by a single sensory neuron, which specifically synapses with a set of giant interneurons (GIs) in the terminal ganglion. These trigger a directed escape run. Severing the sensory axons causes them to degenerate and perturbs escape behavior, which is restored to near normal after 4–6 days. Within this time, afferents regenerate and reestablish arborizations in the terminal ganglion. In most cases, regenerating afferents enter the cercal glomerulus and re-form most of the specific monosynaptic connections they acquired during embryogenesis, although their morphology deviates markedly from normal; these animals reestablish near normal escape behavior. In a few cases, regenerating afferents remain within the cercus or bypass the cercal glomerulus, and thereby fail to re-form synapses with GIs; these animals continue to exhibit perturbed escape behavior. We conclude that in most cases, specific synapses are reestablished and appropriate escape behavior is restored. This regeneration system therefore provides a tractable model for the establishment of synaptic specificity in a simple neuronal circuit. © 1997 John Wiley & Sons, Inc. J Neurobiol 33: 439–458, 1997     

Electrotonic coupling between cercal afferents and giant interneurons in the American cockroach

Stimulation of the cercal nerve of the female American cockroach evokes a short-latency action potential in one giant axon in the ipsilateral connective of the ventral nerve cord. Neither procion yellow nor cobalt passes from the nerve cord into the cercal nerve, and the short-latency response disappears several weeks after removal of the cercus. Therefore, the short-latency spike is not due to a branch of the giant interneuron extending into the cercal nerve, but is presumably due to electrotonic coupling of cercal afferents to the giant. Responses of the presumed electrotonic junction to drugs, varied ionic concentrations and tonicity, and to cold are described. These responses and the impermeability of the junction to procion yellow suggest that the coupling is not by means of a gap junction. There is evidence for electrotonic coupling to another giant axon in the female, but this junction does not ordinarily transmit a spike. Electrotonic coupling is rare in males. In some females action potentials in giant interneurons excite cercal afferents electrically, and the afferents then re-excite the giants chemically. Electrotonic coupling may reduce fatigue and habituation of chemical synapses by depolarizing presynaptic terminals whenever the giants are active.     

Positional information determines the anatomy and synaptic specificity of cockroach filiform hair afferents using independent mechanisms

Summary Mutant first instar cockroaches (Periplaneta americana) with supernumerary filiform hair sensilla on their cerci were used to study the effects of cell body position on axonal morphology and synaptic connections. The wild-type cercus has two hairs, one lateral (L) and the other medial (M), each with an underlying sensory neuron. Silver-intensified cobalt fills show that the supernumerary lateral neuron (SIN) in the mutant has the same shape of arborization as L, and electrophysiological recording shows that it forms synaptic connections with the same subset of giant interneurons (GIs) as L in the terminal ganglion: GI3 and GI6. The supernumerary medial neuron (SuM) has the same axonal morphology as M and synapses with the same GIs as does M: ipsilateral GIs 1 and 2 and contralateral GIs 1, 2, 3, 5 and 6. In 0.1% of approximately 8000 animals screened, a supernumerary hair arose on the cereal midline (C hair). The C neuron sends its axon to the CNS in the same branch of the cereal nerve as the L and SIN, and has a similar arborization. However, the C neuron forms synapses with the same GIs as do M and SuM. Electron microscopy of horseradish peroxidase-injected neurons was used to confirm that the C afferent forms a monosynaptic connection to GI2. It was concluded that the position of the sensory neuron cell body does control its axonal morphology and synaptic connectivity, but that these characteristics are produced by independent mechanisms.Abbreviations GI giant interneuron - L lateral - M medial - SI Space Invader - SuM supernumerary medial - C cereal midline     

Cercal sensory system and giant interneurons in Gryllodes sigillatus

The external morphologies of two cricket species, Gryllodes sigillatus and Gryllus bimaculatus, were investigated. Despite its small body length, G. sigillatus possessed longer cerci and longer cercal filiform hairs than G. bimaculatus. The estimated number of filiform hairs on a cercus was also larger in G. sigillatus than in G. bimaculatus. Wind-sensitive interneurons receiving sensory inputs from cercal filiform hairs and running in the ventral nerve cord (VNC) were investigated in G. sigillatus both morphologically and physiologically. By intracellular staining, these interneurons were proved to be morphologically homologous with previously identified giant interneurons (GIs 8-1, 9-1, 9-2, 9-3, 10-2, and 10-3) in G. bimaculatus and Acheta domesticus. In G. sigillatus, the intensity-response relationship (I-R curve) for each GI was investigated using a unidirectional air current stimulus. The stimulus was applied from 12 different directions, and an I-R curve was obtained for each stimulus direction. Each GI showed a characteristic I-R curve depending on stimulus direction. The directionality curve expressed in terms of threshold velocity showed that each GI had a distinctive directional characteristic. The functional properties of GIs in G. sigillatus, such as I-R curve, threshold velocity, and directional characteristics, were compared with those of homologous GIs in G. bimaculatus in Discussion.     

Identification of thoracic interneurons that mediate giant interneuron-to-motor pathways in the cockroach

Paired intracellular recordings were made to identify thoracic interneurons that receive stable short latency excitation from giant interneurons (GIs). Eight metathoracic interneurons were identified in which EPSPs were correlated with GI activity which was evoked either by wind or intracellular electrical stimulation or occurred spontaneously. In all cases EPSPs in the thoracic interneurons followed GI action potentials faithfully at short latencies. EPSPs associated with GI action potentials consistently represented the upper range of amplitudes of a large sample of EPSPs recorded in the thoracic interneurons. Seven of the interneurons were correlated with activity in ventral GIs but were not correlated with activity in dorsal GIs. Four of these interneurons were part of a discrete population of interneurons whose somata are located in the dorsal posterior region of the ganglion. The eighth interneuron (designated the T cell) was positively correlated with activity in dorsal GIs. The four dorsal posterior group interneurons and the T cell were depolarized intracellularly to establish their potential for generating motor activity. In all cases evoked activity was stronger in leg motor neurons (primarily Ds and the common inhibitor) located on the side contralateral to the interneuron's soma. The results indicate that significant polysynaptic pathways exist by which GI activity can evoke motor activity. The implications of this conclusion to investigations on the cockroach escape system are discussed.     

Ectopic sensory neurons in mutant cockroaches compete with normal cells for central targets.

The cercus of the first instar cockroach, Periplaneta americana, bears two filiform hairs, lateral (L) and medial (M), each of which is innervated by a single sensory neuron. These project into the terminal ganglion of the CNS where they make synaptic connections with a number of ascending interneurons. We have discovered mutant animals that have more hairs on the cercus; the most typical phenotype, called "Space Invader" (SI), has an extra filiform hair in a proximo-lateral position on one of the cerci. The afferent neuron of this supernumerary hair (SIN) "invades the space" occupied by L in the CNS and makes similar synaptic connections to giant interneurons (GIs). SIN and L compete for these synaptic targets: the size of the L EPSP in a target interneuron GI3 is significantly reduced in the presence of SIN. Morphometric analysis of the L afferent in the presence or absence of SIN shows no anatomical concomitant of competition. Ablation of L afferent allows SIN to increase the size of its synaptic input to GI3. Less frequently in the mutant population, we find animals with a supernumerary medical (SuM) sensillum. Its afferent projects to the same neuropilar region as the M afferent, makes the same set of synaptic connections to GIs, and competes with M for these synaptic targets. The study of these competitive interactions between identified afferents and identified target interneurons reveals some of the dynamic processes that go on in normal development to shape the nervous system.     

Two types of information processing in cercal systems of insects: directional sensitivity of giant interneurons

Summary Cercal systems of seven insect species (cricketMelanogryllus desertus, mole cricketGryllotalpa gryllotalpa, katydidsPholidoptera pustulipes andTettigonia viridissima, cockroachesPeriplaneta americana andBlatta orientalis, and locustLocusta migratoria) were examined for direction-sensitive giant interneurons (GIs) that are excited by cercal receptors but have directional preferences independent of cercus position. Such GIs are known for the cricketsAcheta domesticus andGryllus bimaculatus. Directional sensitivity diagrams (DSDs) of GIs were obtained by recording and analysing the electrical responses of abdominal connectives to sound stimuli from various directions. For each animal DSDs were plotted in the form of polar graphs for two or three positions of the stimulated cercus so that the effect of cercus position on the orientation of the DSD could be evaluated.All insects studied had GIs whose DSDs for fixed cercus positions were similar in appearance to the DSDs described for GIs of the cricketsAcheta domesticus andGryllus bimaculatus. Most of these DSDs were shaped like a figure 8 (when airflow is used as the stimulus instead of sound, each DSD has only one lobe). However, not all GIs demonstrated a constant directional preference. GIs with constant directionality were found only inMelanogryllus desertus, Pholidoptera pustulipes, Tettigonia viridissima andLocusta migratoria. In these insects DSDs from one GI plotted for different cercus positions had approximately the same orientation (Figs. 4–7). In contrast, GIs inGryllotalpa gryllotalpa, Periplaneta americana andBlatta orientalis had DSDs whose orientation changed in accordance with a change in position of the stimulated cercus (Figs. 8–10).Thus, direction-sensitive GIs investigated here can be divided into two types: (1) GIs with constant directionality (whose DSDs are fixed to the body, and (2) GIs with variable directionality (whose DSDs are fixed to the cerci). To date, in each species only GIs of the same type have been encountered. This may be an indication that cercal systems can be divided into two categories according to how they process information. However, since we have not tested all GIs in each species, we cannot rule out the possibility that a species might have both types of GIs.Abbreviations DSD directional sensitivity diagram - GI giant interneuron - TAG terminal abdominal ganglion     

Three descending interneurons reporting deviation from course in the locust

Three descending brain interneurons (DNI, DNM, DNC) are described from Locusta migratoria. All are paired, dorsally situated neurons, with soma in the protocerebrum, input dendrites in the proto- and deuterocerebrum, and a single axon running to the metathoracic ganglion and sometimes further. In DNI the soma and all cerebral arborizations lie ipsilateral to the axon. Discrete regions of arborization lie in the ipsilateral and medial ocellar tracts, the midprotocerebrum and the deuterocerebrum. In the other ganglia the axon branches only ipsilaterally, principally laterally in the flight motor neuropil but also towards the midline. DNC is similarly organized to DNI, but the cell crosses the midline in the brain. Soma, the single projection into a lateral ocellar tract, and the midprotocerebral arborization all lie contralateral to the axon. The deuterocerebral arborization is, however, ipsilateral to the axon. The pattern of projections in the remaining ganglia resembles that of DNI. The soma and all cerebral arborizations of DNM lie ipsilateral to the axon. The arborization is only weakly subdivided into protocerebral, deuterocerebral and medial ocellar tract regions. In the remaining ganglia the arborization extends bilaterally to similar areas of both left and right flight motor neuropil. A table of synonymy is given, equating the various names used for these neurons by previous authors. The morphology correlates well with the known input and output connections. They respond physiologically to deviations from the normal flight posture mediated by ocelli, eyes and wind hairs and connect to the thoracic flight apparatus.     

Indirect synaptic inputs from filiform hair sensory neurons contribute to the receptive fields of giant interneurons in the first-instar cockroach

The first-instar cockroach, Periplaneta americana, detects air movements using four filiform hair sensilla, which make synaptic connections to seven pairs of giant interneurons (GIs) in the terminal abdominal ganglion. The directional sensitivities of some of the GIs, predicted from their patterns of monosynaptic inputs, may not be the same as in the second instar or adult. Intracellular recordings were made to determine the contribution of polysynaptic inputs to the receptive fields of first-instar GIs. The ventral GI1, and the dorsal GI5, GI6, and GI7 were all found to have indirect synaptic inputs from filiform afferents. The indirect inputs were excitatory to GI1, GI5, and GI7, and inhibitory to GI6 and GI7. The indirect excitatory input to GI1 was predicted to alter qualitatively its receptive field, allowing it to respond to wind from the side of the animal, as in the adult. Inhibition was predicted to sharpen the receptive fields of GI6 and GI7. The inhibitory postsynaptic potentials reversed 6–8 mV below resting potential and were blocked by picrotoxin, indicating that they are GABAergic. Indirect excitation also altered the predicted receptive field of GI7, one of the inputs being an unusual “off-response” to movement of a filiform hair in its inhibitory direction. Accepted: 19 June 1998     

Actions of phencyclidine and its thienylpyrrolidine analogue on synaptic transmission and axonal conduction in the central nervous system of the cockroach Periplaneta americana

The effects of phencyclidine (PCP) and its thienylpyrrolidine analogue (TCPY) were tested on conduction processes in the isolated axon of giant interneurone 2 (GI 2) of the cockroach Periplaneta americana and on binding of [³H]PCP and [¹²⁵I]α-bungarotoxin to membranes from Periplaneta brain and nerve cord. Their actions on synaptic transmission between cercal sensory neurones and GI 2, where acetylcholine is the likely neurotransmitter, were also examined. PCP suppressed both sodium and potassium currents in the axonal membrane at 5.0 × 10^?4 M. Block was reversible on rebathing the axon in normal saline. TCPY exerted similar effects on the axon, though at slightly higher concentrations. Excitatory postsynaptic potentials (EPSPs) recorded from GI 2 in response to electrical stimulation of cercal nerve XI were progressively blocked by 5.0 × 10^?4 M PCP following a brief initial enhancement (?10%) of EPSP amplitude. The depolarizing response of GI 2 to ionophoretically applied acetylcholine was also blocked at this concentration, indicating a postsynaptic action of PCP at the acetylcholine receptor-ion channel of GI 2. TCPY also blocked synaptic transmission at synapses between cercal afferents and GI 2, but, in contrast to the actions of PCP, EPSP block was accompanied by depolarization. PCP and TCPY inhibited [³H]PCP binding to nerve cord and brain membranes with multiple affinities, suggesting multiple molecular targets. They also modified aspects of the kinetics of [¹²⁵I]α-bungarotoxin binding to the nicotinic acetylcholine receptor in these membranes and enhanced conversion of the receptor to the high affinity desensitized state. At higher concentrations they also inhibited [¹²⁵I]α-bungarotoxin binding. PCP was more potent than TCPY in inhibiting [³H]PCP binding but less potent on [¹²⁵I]α-bungarotoxin binding. Thus PCP and TCPY, which are structurally very similar, interact with several molecular targets in insect neuronal membranes, including sodium and potassium channels and acetylcholine receptors.     

Information processing in a cricket ganglion: The response of giant fibres to sound pulses

The response of giant fibres in the ventral nerve cord to stimulation of cercal afferents with pulses of sound was studied in the domestic cricket, Acheta domesticus. Pulses at 450 Hz gave the highest frequency response in several classes of units, and were therefore used as stimuli in subsequent experiments. In intact animals the response of the giant fibres to bilateral cercal stimulation showed a characteristic high frequency ‘on’ response followed by steady firing of some units for the duration of the sound pulse. The end of each pulse was followed by a short period of inhibition of the tonic units.Cercal amputation and other experiments showed that input from cercal afferents excites both large and small ipsilateral giants, and excites small and inhibits large contralateral giants. Descending input from higher neural centres in intact animals tends to reduce the responses to the stimuli. It is suggested that a function of the contralateral excitatory and inhibitory effects is to sharpen the ‘on’ response of the giant fibres to sound stimuli in intact animals.     

Dendritic calcium accumulation regulates wind sensitivity via short-term depression at cercal sensory-to-giant interneuron synapses in the cricket

An in vivo Ca2+ imaging technique was applied to examine the cellular mechanisms for attenuation of wind sensitivity in the identified primary sensory interneurons in the cricket cercal system. Simultaneous measurement of the cytosolic Ca2+ concentration ([Ca2+]i) and membrane potential of a wind-sensitive giant interneuron (GI) revealed that successive air puffs caused the Ca2+ accumulation in dendrites and diminished the wind-evoked bursting response in the GI. After tetanic stimulation of the presynaptic cercal sensory nerves induced a larger Ca2+ accumulation in the GI, the wind-evoked bursting response was reversibly decreased in its spike number. When hyperpolarizing current injection suppressed the [Ca2+]i elevation during tetanic stimulation, the wind-evoked EPSPs were not changed. Moreover, after suprathreshold tetanic stimulation to one side of the cercal nerve resulted in Ca2+ accumulation in the GI's dendrites, the slope of EPSP evoked by presynaptic stimulation of the other side of the cercal nerve was also attenuated for a few minutes after the [Ca2+]i had returned to the prestimulation level. This short-term depression at synapses between the cercal sensory neurons and the GI (cercal-to-giant synapses) was also induced by a depolarizing current injection, which increased the [Ca2+]i, and buffering of the Ca2+ rise with a high concentration of a Ca2+ chelator blocked the induction of short-term depression. These results indicate that the postsynaptic Ca2+ accumulation causes short-term synaptic depression at the cercal-to-giant synapses. The dendritic excitability of the GI may contribute to postsynaptic regulation of the wind-sensitivity via Ca2+-dependent depression.     

Postembryonic changes in the response properties of wind-sensitive giant interneurons in cricket

The intensity-response (I-R) relations for four wind-sensitive giant interneurons (GIs 8-1, 9-1, 9-2 and 9-3) in the fourth-, sixth- and last-instar nymphs of the cricket, Gryllus bimaculatus, were investigated using a unidirectional air current stimulus in order to explore the functional changes of GIs during postembryonic development. Contrary to our expectations, the response properties of GIs in nymphs were largely different from those in adults. The response magnitude of GI 8-1 in an intact cricket decreased during development, i.e. the GI in younger insects showed a larger response magnitude. Although the response magnitudes of GIs 9-1 and 9-2 were almost identical during the nymphal period, a significant decrease was observed after the imaginal ecdysis. During the nymphal period, the response magnitude of GI 9-3 increased according to the developmental stage. However, it decreased significantly after the imaginal ecdysis. We also investigated the response magnitudes of the GIs in nymphs after unilateral cercal ablation. From the results of ablation experiments, the changes in excitatory and/or inhibitory connections between filiform hairs and each GI during postembryonic development were revealed.     

Morphology of soma and dendrites of the giant fiber system in the sixth abdominal ganglion of the cockroach

This study, using the cobalt chloride technique, clarifies the origin of the giant axons in the cockroach, Periplaneta. Each giant axon in the ventral nerve cord arises from a single cell body located in the sixth abdominal ganglion. The position of the soma is always contralateral to the giant axon; it projects anteriorly. In six giant neurons, the axonic and dendritic branches are ipsilateral while the somata are contralateral. In two neurons, both the soma and the dendritic branches are ipsilateral while the axons are contralateral. The dendritic arborizations of the giant neurons form a dense and compact mass of neuropile in each half of the posterior and middorsal part of the ganglion where sensory fibers, primarily from the cercal nerves terminate. The relation of these findings to earlier electrophysiological studies is discussed.     

Innervation of cockroach cercal receptors as revealed by horseradish peroxidase (Insecta,Blattodea)

Summary The innervation of cerci of a desert burrowing cockroach, Arenivaga sp., was determined by horseradish peroxidase backfilling of the cercal nerve and histochemistry. The procedure yielded a high percentage of successful fills and in many cases every neuron filled completely, including dendrites and axons of less than one m. The innervation of the cerci was found to be highly ordered. Upon entering the cercus, the cercal nerve splits into bilateral branches, one on each side of the midline. The nerves branch again at each segment to form fascicles of sensory neurons which innervate the trichobothria, sensilla chaetica and tricholiths, each with a single bipolar neuron. While the cell bodies of neurons are of similar dimensions, the dendrites to the tricholiths are much longer and terminate on the midline side of the sensilla socket where the tricholith shaft attaches.     

Proportional inhibition in the cricket medial giant interneuron

Inhibitory effects on the number of wind-evoked impulses were studied in the medial giant interneuron of the cricket, Gryllus bimaculatus. The interneuron receives an inhibitory input from wind receptors on cercus ipsilateral to its soma. Using a dual channel wind stimulator, the intensity of inhibitory input was changed over 1,000-fold and effects on the number of spikes were observed. The ipsilateral inhibition reduced the number of outgoing spikes from a level elicited by excitation alone and it did so in proportion to the level of wind responsiveness displayed by each cell. A proportional coefficient of inhibition was derived and its value depended on the level of total excitation of the medial giant interneuron. The medial giant interneurons with high excitation showed a smaller value of the coefficient than those with low excitation. The proportional inhibition of the medial giant interneuron by the ipsilateral cercus suppresses the number of its spikes to a reasonable level for a wide range of stimulus intensities under natural conditions.     

The effects of transplantation and regeneration of sensory neurons on a somatotopic map in the cricket central nervous system

The restoration of the cercal afferent projection of crickets was examined after severing the cercal nerve or amputating the cercus and reimplanting it. After either maneuver the sensory neurons regenerated arborizations in the central nervous system (CNS) within about 1 month. In order to assess the role of the pathway taken to the CNS in controlling the growth of the terminal arborization, we transplantated left cerci to the right side of the host. The operation mismatched the mediolateral axes of host and graft tissues. In one-third of the neurons examined, the axon trajectories of the regenerated neurons were altered. The terminal arborizations in these cases were unusual; for example, one neuron arborized in an abnormal area as well as in its normal area. In rare instances this neuron arborized only in incorrect areas of the CNS. Thus, it appears that axon pathway can have an effect on the central structure of sensory neurons. However, in most cases after the surgery, the neurons were able to reach their proper target areas even by circuitous routes. The proximodistal coordinate of the map is isomorphic with sensory neuron age, because the most distal receptors are produced early in postembryonic development and new ones are added proximally at each molt. We tested the possibility that the order of differentiation was critical for generating the afferent projection with two experiments. First, the distal cercus including the distal members of the clavate array was amputated. The specimen regenerated an entire distal cercus including distal clavate receptors. When newly generated, distal neurons were stained, the terminal arbors were identical to the amputated neurons they replaced. In this case, both age and order of arrival were reversed from normal yet the topographic projection pattern was not altered. Second, we transplanted young cerci onto older specimens and then examined the regenerated arbors of the transplanted sensory neuron. The immature neuron arborized in the adult nervous system exactly as the mature homolog. Thus the age of a sensory neuron did not appear to be a controlling variable in the elaboration of a terminal arborization. The significance of these results is discussed in the context of two models for development of orderly neuronal connections.