Wing receptors of the American cockroach Periplaneta americana]

Wing receptors of the cockroach have been studied using staining technique with methylene blue in living animals. Five types of the receptors were found: trychoid hairs, bristles, complaniform sensillae, chordotonal organs and multiterminal neurons. The majority of the receptors is located at the lower surface of the wing, especially along its ribs. Together with primitive features in the structure (polyneuronal origin of hairs and bristles, poor content of chordotonal organs, absence of distinct groups of companiform sensillae), some specialization of wing receptors with respect to flight function is noted (concentration of proprioceptors along the main mechanical axis of the wing and formation of distinct rows by the companiform sensillae).     

Localization of the receptors that initiate and maintain flight in the cockroach, Periplaneta americana

Using local air streams, screening and surgical removal of the cerci and antennae, studies have been made on the receptors which provide for initiation and maintenance of the flight in the cockroach. It was shown that in suspended insect which lacks any contacts of legs with the base, the flight may be initiated by direct air currents either on the cerci, or antennae. Receptors which maintain the flight are located on the antennae and wings, the prolonged flight being provided mainly by antennae receptors.     

Neuromodulation of flight initiation by octopamine in the cockroach Periplaneta americana

We have tested the effect of a known insect neuromodulator, octopamine, on flight initiation in the cockroach. Using minimally dissected animals, we found that octopamine lowered the threshold for windevoked initiation of flight when applied to either of two major synaptic sites in the flight circuitry: 1) the last abdominal ganglion, where wind-sensitive neurons from the cerci excite dorsal giant interneurons, or 2) the metathoracic ganglion, where the dorsal giant interneurons activate interneurons and motoneurons which are involved in producing the rhythmic flight motor pattern in the flight muscles (Fig. 2).Correlated with this change in flight initiation threshold, we found that octopamine applied to the last abdominal ganglion increased the number of action potentials produced by individual dorsal giant interneurons when recruiting the cereal wind-sensitive neurons with wind puffs (Figs. 3, 4, 5) or with extracellular stimulation of their axons (Fig. 6). Octopamine increases the excitability of the giant interneurons (Figs. 7, 8). Also, when we stimulated individual dorsal giant interneurons intracellularly, the number of action potentials needed to initiate flight was reduced when octopamine was applied to the metathoracic ganglion (Fig. 9).Abbreviations EMG electromyogram - dGIs dorsal giant interneurons - GI giant interneuron - A6 sixth abdominal ganglion - T3 third thoracic ganglion - EPSP excitatory postsynaptic potential     

The effect of temperature on flight initiation in the cockroach Periplaneta americana

The effect of temperature during development of the flight system of the American cockroach was tested. Animals were raised at three different temperatures from egg cases to adulthood then various parameters of flight were tested. Animals raised at cooler temperatures were found to require significantly stronger wind puffs to initiate flight than did animals raised in warmer temperatures. Some animals were raised at one temperature during embryonic development (i.e. while the animals were still in egg cases) and then switched to a different temperature for nymphal development. In these cases only the temperature experienced during embryonic development had a significant permanent effect on flight. Parameters associated with pattern generation such as interburst interval were not affected by temperature during either developmental period.     

Functional role of leg receptors of the cockroach Periplaneta americana in the system of walking control

This work deals with study of role of the hairplate and of campaniform sensillae (CS) on legs of the cockroach Periplaneta americana in the system of walking control. Three receptors were shown to induce their regulatory, correctional effect on the rhythm of the cockroach steps depending on the external circumstances. These effects are mainly realized only at slow walking.     

Effects of oxygen on the cercal receptors of the cockroach Periplaneta americana

• 1.1. The activity of the cercal nerve XI and giant interneurons of the cockroach Periplaneta americana is much more intense in situ than in vitro, despite perfusion of the sixth abdominal ganglion by oxygenated saline.
• 2.2. The background cercal nerve activity increases in vitro upon oxygenation from a negligible level. It persists for about 10 min following cessation of oxygenation. The activity in situ remains unaffected.
• 3.3. Oxygenation also substantially increases the frequency of sensory spikes evoked during mechanical stimulation of cercal receptors in vitro, as well as the frequency of generated EPSPs in the interneurons which integrate the cercal activity. The latter effect is apparently due to the increased frequency of afferent spikes.
• 4.4. The intense activity detected in vitro in oxygenated preparations appears to be closer to that existing in situ.

     

The mechanosensory apparatus of the femoral tactile spine of the cockroach,Periplaneta americana

Summary Tactile spines are large cuticular sense organs that appear to provide insects with a sense of touch which is spatially coarse but of great sensitivity. Cockroach legs have a number of these spines on each leg and a particularly prominent spine on the end of each femur, the femoral tactile spine. The ease of recording afferent activity from this spine during mechanical stimulation has made it one of the most thoroughly studied insect mechanoreceptors and yet it has never been examined by electron microscopy.We report here the results of an examination of the femoral tactile spine by both scanning and transmission electron microscopy, as well as by light microscopy. The spine is shown to be innervated by a single sensory bipolar neuron with its soma located in the base of the spine. A canal through the wall of the spine leads to the outside and emerges just above the junction between the base of the spine and its articulating socket membrane. The sensory dendrite of the neuron passes from the soma through this canal and forms a modified ciliary sensory ending with the typical dendritic sheath and dense tubular body that is characteristic of insect mechanosensory cuticular sensilla. The tubular body is embedded in a cuticular terminal plug which closes the exterior end of the canal but appears to be fastened to the spine by a very flexible ring of cuticle. This plug is connected to the socket membrane by a specialized socket attachment which presumably serves to move the plug relative to the wall of the spine during movement of the spine within the socket. The morphology of this sensillum is discussed in terms of the possible ways in which it is stimulated by movements of the spine and also in light of the dynamic behaviour of the receptor which is now very well described.Supported by the Canadian Medical Research Council. The authors gratefully acknowledge the expert technical assistance of Sita Prasad and Rodney Gramlich     

Classical olfactory conditioning in the cockroach Periplaneta americana

We established a classical conditioning procedure for the cockroach, Periplaneta americana, by which odors were associated with reward or punishment. Cockroaches underwent differential conditioning trials in which peppermint odor was associated with sucrose solution and vanilla odor was associated with saline solution. Odor preference of cockroaches was tested by allowing them to choose between peppermint and vanilla sources. Cockroaches that had undergone one set of differential conditioning trials exhibited a significantly greater preference for peppermint odor than did untrained cockroaches. Memory formed by three sets of differential conditioning trials, with an inter-trial interval of 5 min, was retained at least 4 days after conditioning. This conditioning procedure was effective even for cockroaches that had been harnessed in plastic tubes. This study shows, for the first time in hemimetaborous insects, that both freely moving and harnessed insects are capable of forming olfactory memory by classical conditioning procedure. This procedure may be useful for future electrophysiological and pharmacological studies aimed at elucidation of neural mechanisms underlying olfactory learning and memory.     

Multisensory control of escape in the cockroach Periplaneta americana

1. All giant interneurons (GIs) were ablated from the nerve cord of cockroaches by electrocautery, and escape behavior was analyzed with high-speed videography. Animals with ablations retained the ability to produce wind-triggered escape, although response latency was increased (Table 1, Fig. 4). Subsequent lesions suggested that these non-GI responses depended in part on receptors associated with the antennae.
2. Antennal and cereal systems were compared by analyzing escape responses after amputating either cerci or antennae. With standard wind stimuli (high peak velocity) animals responded after either lesion. With lower intensity winds, animals lost their ability to respond after cereal removal (Fig. 6).
3. Removal of antennae did not cause significant changes in behavioral latency, but in the absence of cerci, animals responded at longer latencies than normal (Fig. 7).
4. The cercal-to-GI system can mediate short latency responses to high or low intensity winds, while the antennal system is responsive to high intensity winds only and operates at relatively longer latencies. These conclusions drawn from lesioned animals were confirmed in intact animals with restricted wind targeting the cerci or antennae only (Fig. 9).
5. The antennae do not represent a primary wind-sensory system, but may have a direct mechanosensory role in escape.

     

Nicotinic acetylcholine receptors on a cholinergic nerve terminal in the cockroach,Periplaneta americana

Summary Intracellular microelectrode recording and ionophoretic application of carbamylcholine (CCh) were used to compare the cholinergic sensitivity of postsynaptic dendrites of an identified neurone with that of an identified presynaptic cholinergic axon.The axon of the lateral filiform hair sensory neurone (LFHSN) in the first-instar cockroachPeriplaneta americana was found to be as sensitive to CCh as the dendritic regions of giant interneurone 3 (GI 3). The CCh response of both neurones was unaffected by replacing Ca²⁺ with Mg²⁺, confirming that the ACh receptors are present on the neurones under test. The CCh response of both neurones was mimicked by ionophoretic application of nicotine. The responses were blocked by 10^–5 M mecamylamine and 10^–6 M d-tubocurarine and were not affected by muscarinic antagonists, suggesting that the ACh receptors present on GI 3 and LFHSN are predominantly nicotinic.The muscarinic agonist oxotremorine and the antagonists atropine and quinuclidinyl benzilate had no modulatory effect on LFHSN-GI 3 synaptic transmission.The latency of the LFHSN response to CCh was consistent with the hypothesis that ACh receptors are situated on the main axon/terminal within the neuropil of the ganglion. It has previously been shown that this region of the axon does not form output synapses (Blagburn et al. 1985a). This indirect evidence indicates that presynaptic or extrasynaptic ACh receptors are present in the membrane of a cholinergic axon.LFHSN was depolarized by synaptically-released ACh after normal or evoked spike bursts, suggesting that the nicotinic ACh receptors act as autoreceptors. However, it was not possible to obtain direct evidence to support the hypothesis that these receptors modulate ACh release.Abbreviations CCh carbamylcholine - GI giant interneurone - FHSN filiform hair sensory neurone - LFHSN lateral filiform hair sensory neurone - R _in input resistance - V depolarization - V _m resting potential     

Biosynthesis of 3-methylpentacosane in the cockroach Periplaneta americana.

The biosynthesis of 3-methylalkanes was investigated in the cockroach $\text{Periplaneta americana}$. Between 0.2 and 0.3 percent of the labelled acetate and propionate injected into the insect was incorporated into the cuticular hydrocarbons, compared to 0.01 percent for labelled isoleucine. Twenty-three ± four percent of the [2-¹⁴C]acetate, 42 ± 3 and 44 ± 4 percent of the [2-¹⁴C] and [3-¹⁴C]propionate, and 75 ± 5 percent of the [1-¹⁴C]propionate incorporated into the cuticular hydrocarbons was found in 3-methylpentacosane. These results indicate that propionate serves as the source of the branching methyl group, suggesting a pathway in which this precursor is incorporated during the penultimate step in 3-methylalkane biosynthesis in insects.     

Aminergical regulation of pheromone sensillae in the cockroach Periplaneta americana

Vast adaptability of insects is provided substantially by fast tining of physiological functioning of an organism to conform to the permanently changing environmental conditions. One of the mechanisms of plasticity in insects is modulation of performance of their sense organs by neurohormones. Activity of at least three out of four receptor cells located in cockroach pheromonesensitive sensilla is under influence of octopamine. Increase in firing rate of pheromone receptor cells and decrease in electroantennogram amplitude is accompanied by enhanced behavioural responses of male cockroaches to sex pheromone. The effect of octopamine on reception of a repellent (1,8-cineole) by an insect is reported for the first time. Simultaneous modulation of responses of receptor cells located in sex specific sensilla to semantically different odorants implies their cooperation in formation of insect's behaviour.     

Type II neurons in the trunk of the cockroach Periplaneta americana

Staining the nervous system by methylene blue, studies have been made on the topography and structure of type II neurones in the trunk of the cockroach. Small quantity of cells innervating various tissues was found together with 3 varieties of neurones, located near the nervous trunks, as well as 4 pairs of the abdominal stretch receptors (one pair of unicellular and one pair of bicellular receptors in tergites and sternites).     

Duplication of a peripheral sensory neuron in the cockroach Periplaneta americana

Summary We have recently examined the electrophysiology and ultrastructure of approximately 100 tactile spines from the metathoracic legs of adult cockroaches. In only one animal the single sensory neuron that innervates the spine was replaced with a pair of apparently identical neurons which we believe were both functional. As far as we are aware this is the first reported study of unprovoked duplication in a peripherally-located insect sensory neuron.Supported by the Canadian Medical Research Council and the Alberta Heritage Foundation for Medical Research     

Glial cells in peripheral nerves of the cockroach, Periplaneta americana

The ultrastructural organization and the junctional complexes of peripheral nerves have been investigated in the cockroach Periplaneta americana. Nerve 5 is surrounded by a layer of connective tissue, the neural lamella, beneath which is a layer of perineurial glial cells wrapping the axons. Adjacent perineurial cells are joined to one another by septate, gap and tight junctions. Septate and gap junctions were observed in freeze-fracture replicas of main trunk nerve 5. Septate junctions were found as rows of PF particles mainly in perineurial cell membranes. Gap junctions exhibited EF macular aggregates in perineurial and subperineurial glial cells. During incubations in vivo with extracellularly applied ionic lanthanum, the lanthanum did not penetrate beyond the perineurium. Where nerve 5 branches and contacts the muscle, lanthanum penetrated freely between the muscle fibres and the nerve branches. In small peripheral branches where the axons are surrounded by single a glial layer, lanthanum is unable to penetrate to the axolemma.