Control of the circadian rhythm of locomotor activity in the house cricket

A detailed analysis was made of the locomotor activity of Acheta domesticus under conditions of 12 hr light and 12 hr darkness (LD 12 : 12) and of continuous darkness (DD). Under LD 12 : 12 it was found that there are three types of insects: (1) those beginning the period of increased locomotor activity immediately after darkness falls, (2) considerably before this time, and (3) considerably after this time. Under DD conditions the greater amount of the insects have a free-running rhythm shorter than 24 hr, while only a small percentage have a rhythm of more than 24 hr.Destruction of the neurosecretory cells of the pars intercerebralis by means of radio waves leads to the formation of hyperactivity and loss of locomotor activity rhythm when more than half of these cells are destroyed.Injection of reserpine into the insect's haemolymph with doses of 10 μg/g of body weight results in a reduction in locomotor activity and produces arrhythmicity for 2 to 3 days under LD 12 : 12 conditions. Under DD conditions, however, this same dose results in a total and irretrievable loss of free-running rhythm. Histological studies of the brain of crickets following injection of reserpine show a large degree of accumulation of neurosecretion in the cells of the pars intercerebralis as compared with control insects.A hypothesis is put forward as to the way in which the brain centres regulating locomotor rhythm act in crickets.     

Experimental evidence for a neuroendocrine control of ecdysone biosynthesis in adult females of Locusta migratoria

The considerable increase in ecdysteroid concentration which occurs in normal Locusta ovaries at the end of each cycle of oöcyte maturation is prevented if the median neurosecretory cells of the pars intercerebralis are cauterized, or if the corpora cardiaca are excised 24 hr before the onset of ecdysone synthesis in normal females. Implantation of additional brain-corpora cardiaca complexes into young vitellogenic females advances the time of ecdysone synthesis by some 12 hr. Oöcyte growth itself is not affected in these different types of experiments.It is inferred from the data of the present study that ecdysone synthesis in the follicle cell epithelium of maturing Locusta ovaries is stimulated by a neurohormone produced in the median neurosecretory cells of the pars intercerebralis and secreted into the blood via the corpora cardiaca.     

Effects of ablation of the pars intercerebralis on ecdysteroid quantities and yolk protein expression in the blowfly Protophormia terraenovae

Quantities of ecdysteroid are compared in the haemolymph and ovaries of the blowfly Protophormia terraenovae Robineau‐Desvoidy (Diptera: Calliphoridae) under reproductive (LD 18 : 6 h at 25 °C) and diapause (LD 12 : 12 h at 20 °C) conditions. The effects of ablation of the pars intercerebralis or ovaries on ecdysteroid quantities and of ablation of the pars intercerebralis on yolk protein expression are examined. Under reproductive conditions, the levels of ecdysteroid in vitellogenic females are high, although the levels in previtellogenic females and females with mature ovaries are low. Under diapause conditions, there are low quantities of ecdysteroid in both the haemolymph and ovaries. Ecdysteroid titres in the haemolymph are not significantly affected by the removal of the ovaries, suggesting that tissues other than the ovaries are also involved in the production of ecdysteroids. Reproductive females in which the pars intercerebralis of the brain is experimentally ablated have ecdysteroid levels that are not significantly different from sham‐operated or intact females. However, yolk protein expression in the fat body is suppressed after removal of the pars intercerebralis. These results suggest that the suppression of ecdysteroid levels in the haemolymph and ovaries is associated with reproductive diapause, and that the pars intercerebralis could play a role in yolk protein synthesis without mediating ecdysteroid production.     

Rôle of eyes,optic lobes,and pars intercerebralis in locomotory and stridulatory circadian rhythms of Teleogryllus commodus

Locomotory and stridulatory activity rhythms of male crickets (Teleogryllus commodus) were assayed simultaneously following various experimental procedures. These included (a) severing the pathways between the ocelli and the brain, between the ommatidia and the optic lobes, or between the optic lobes and the brain, and (b) RF cauterization of the pars intercerebralis. The results indicate that (1) light-dark cycles which entrain both rhythms are perceived by the compound eyes and not by the ocelli; (2) loss of connexion between the brain and the optic lobes leads to arrhythmicity in both behaviours, but a single optic lobe can maintain rhythmicity; (3) absence of neurosecretory cells in the pars intercerebralis is correlated with loss of stridulatory activity and arrhythmicity in locomotory behaviour. It is suggested that the pars intercerebralis serves as a site of coupling between a circadian pacemaker and various overt behaviours. However, intermediate control by the pars intercerebralis is assumed to be exerted via channels that can be either hormonal or purely neuronal in nature.     

L'action exercée par l'appareil endocrine sur les phases tardives de l'ovogenèse chez Locusta migratoria

Most studies dealing with the endocrine control of oogenesis are focused on vitellogenesis, but the later events of oogenesis: vitelline membrane formation and choriogenesis have received less atention. In Locusta migratoria, the corpora allata evidently control vitellogenesis, but seem to have no bearing upon the formation of the vitelline membrane or the chorion. If the insects are deprived of their CA at the time when the oocyte length is around 3.5 to 4 mm, (normal length at egg laying: 6.5 mm) vitelline membrane formation and the chorion production are unaffected. In the same species, the electrocoagulation of the pars intercerebralis or excision of corpora cardiaca disturb oogenesis; vitelline membrane material is synthesized and secreted, but the primary granules fail to join each other and to transform into vitelline membrane and the production of chorionic material is disturbed.The rER of the follicle cell seems quite active but the substance elaborated accumulates in the Golgi saccules, and therefore the cytoplasm contains only very few secretory granules. The implantation of supernumerary pars intercerebralis and corpora cardiaca into immature females induces precocious deposition of the vitelline membrane which is complete in 5.0 mm oocytes (instead of 5.6 to 6.0 mm) and chorion formation is completed in 5.5 mm oocytes (instead of 6.0 to 6.3 mm). Ecdysone is secreted in the ovaries at the end of oogenesis. We tested the result of injecting ecdysone to immature females. It results in hastening oocyte growth during 24 hr, but this accelerated growth is followed by degeneration.     

Precocene sensitivity of corpora allata in adult female Locusta migratoria after electrocoagulation of the pars intercerebralis neurosecretory cells

Destruction, by electrocoagulation, of the median neurosecretory cells of the pars intercerebralis of 2-day old adult female Locusta migratoria completely suppressed normal juvenile hormone-biosynthetic activity of the corpora allata in most animals. For example, 6 days after electrocoagulation the rates of spontaneous juvenile hormone biosynthesis, measured by radiochemical assay of freshly isolated glands, showed a median value of less than $\text{1}\text{100}$ that of the corresponding sham operated controls, which were then in mid-vitellogenesis. Injection of graded doses (200–1600 μg) of precocene I at this time, followed by assays five days later, resulted in a similar decline of both corpus allatum volume and precocene epoxidase activity (measured by radiochemical assays of precocene I dihydrodiol formation in vitro) in pars intercerebralis-coagulated and sham-operated animals, when expressed as a percentage of their own zero precocene controls. Electrocoagulation of the pars intercerebralis largely prevented the normal increase in both corpus allatum volume and its epoxidase activity, so that by age 13 days these parameters were about 2.5-fold lower in coagulated vs control (sham operated) animals. In fact, electrocoagulation had no marked effect on the value of epoxidase activity per unit corpus allatum volume. It is concluded that the corpora allata from this species and stage are sensitive to precocene irrespective of whether they are active in biosynthesis of juvenile hormone.     

Rupture de la diapause ovarienne d'Anacridium aegyptium par stimulation électrique des cellules neurosécrétrices médianes de la pars intercerebralis

Oögenesis and the physiological activity of the corpora allata were studied in adult females of the Egyptian locust (Anacridium aegyptium), in ovarian diapause, after electrical stimulation in vivo of the pars intercerebralis. This stimulation provokes (1) a decrease in the quantity of fuchsinophilic material present in the median neurosecretory cell bodies and in the internal cardiac tract, (2) an increase in the physiological activity of the corpora allata (measured by its chromatropic effect on larvae of Locusta), and (3) rupture of the ovarian diapause (advance of maturation of the oöcytes and oviposition by 5 months, and initiation of the ovarian cycle).In the control animals, the same electrical stimulations of various regions of the central nervous system (tritocerebrum, first ganglion of the abdominal cord) have no effect on these phenomena.In allatectomized females, electrical stimulations of the pars intercerebralis are followed by a slight growth of oöcytes, without a deposit of yellow vitellus. The diapause is not broken. Section of the allatocardiac nerves or rupture of the allatocardiac and allato-suboesophageal nervous connexions do not change the physiological state of the corpora allata. In the case of females in which the corpora allata have been disconnected, electrical stimulations of the pars intercerebralis succeed in activating the corpora allata and breaking the ovarian diapause. The aggregate of these results confirms that in locusts the control of the brain over the physiological activity of the corpora allata is above all neuroendocrine.     

Système endocrine et physiologie de la diapause imaginale chez le criquet égyptien, Anacridium aegyptium

The Egyptian locust, Anacridium aegyptium, has four protocerebral neurosecretory centres: the A to B neurosecretory cells of the pars intercerebralis (the A cells are rich in fuchsinophil material and the B cells are devoid of fuchsinophil neurosecretion), the voluminous C neurosecretory cells poor in neurosecretion, and the median sub-ocellar neurosecretory cells.From September to the beginning of January, imaginal diapause is characterized by an accumulation of the median neurosecretion in the pars intercerebralis-corpora cardiaca system, by small corpora allata, and, in the female, by a stop in oöcyte development although the male's sexual activity is still not altered. Allatectomy suppresses neither the male's sexual behaviour nor its fecundity. From January, the increase of the photoperiod causes a release of the median neurosecretion in both sexes, an increase of the volume of the corpora allata, and breaks ovarian diapause.In autumn, the implantation of the male's or female's corpora allata of Anacridium does not stimulate ovarian growth of diapausing females. On the contrary, the implantation of corpora allata or of pars intercerebralis or of corpora cardiaca of Locusta migratoria migratorioides (locust without diapause) causes ovarian development of the diapausing females of Anacridium. Thus, in the two sexes of the Egyptian locust, the corpora allata are inactive during the female ovarian diapause. The imaginal diapause of Anacridium affects both sexes (stocking of median neurosecretion, arrest of the corpora allata). If diapause does not seem to affect the male's development, it is because its sexual activity is free from the pars intercerebralis and corpora allata.The corpora allata of Anacridium show a sexual dimorphism in the active adult: they are smaller in the male and have more mitosis in the female. An explanation of this dimorphism is advanced.     

Neurons projecting to the retrocerebral complex of the adult blow fly, Protophormia terraenovae

Anatomical study of neurons projecting to the retrocerebral complex of the adult blow fly, Protophormia terraenovae, was done by NiCl2 filling and immunocytochemistry. Retrograde filling through the cardiac-recurrent nerve labeled three groups of neurons in the brain/subesophageal ganglion: (1) paramedial clusters of the pars intercerebralis, (2) neurons in each pars lateralis, and (3) neurons in the subesophageal ganglion. The pars intercerebralis neurons send prominent axons into the median bundle and exit from the brain via the contralateral nervus corporis cardiaci. Based on the projection pattern, two types of the pars lateralis neurons can be distinguished: the most lateral pairs of neurons contralaterally extend through the posterior lateral tract and the remainder ipsilaterally extend through the posterior lateral tract. The neurons in the subesophageal ganglion run through the contralateral nervus corporis cardiaci. The dendritic arborization of the pars intercerebralis and pars lateralis neurons is restricted to the superior protocerebral neuropil and to the anterior neuropil of the subesophageal ganglion where the neurons in the subesophageal ganglion also project. Retrograde filling from the corpus allatum indicated that the pars lateralis neurons and a few pars intercerebralis neurons project to the corpus allatum, but that the neurons in the subesophageal ganglion do not. Orthograde filling from the pars intercerebralis and staining by paraldehyde-thionin/paraldehyde-fuchsin indicated that the pars intercerebralis neurons project primarily to the corpus cardiacum/hypocerebral ganglion complex. Immunostaining with a polyclonal antiserum against diapause hormone, a member of the FXPRLamide family, suggests that some of the subesophageal ganglion neurons contain FXPRLamide-like peptides.     

The intensity of pre- and post-copulatory mate guarding in relation to spermatophore transfer in the cricket Gryllus bimaculatus

While post-copulatory mate guarding has been well documented in field crickets (Orthoptera: Gryllidae), the occurrence of pre-copulatory mate guarding in this family has been largely overlooked. We examined the relationship between the intensity of two components of mate guarding (body judders and antennal whips) and the time before and after copulation. We found that when male Gryllus bimaculatus encounter a female but do not have a spermatophore ready to transfer, they engage in pre-copulatory mate guarding that is very similar to post-copulatory mate guarding. The intensity of pre-copulatory mate guarding increased up to the point at which the male was ready to transfer his spermatophore. Following copulation, the intensity of mate guarding initially remained high before declining, after which it began to increase again just before the male resumed courtship stridulation. We interpret this pattern of post-copulatory mate guarding as being consistent with both the ejaculate-protection and spermatophore-renewal hypotheses for the function of mate guarding. We found no significant relationship between mate guarding intensity and male body mass.     

Insemination of the monogenean Neobenedenia girellae (Capsalidae,Benedeniinae)

In vitro spermatophore formation and insemination of Neobenedenia girellae (Monogenea: Capsalidae, Benedeniinae) were recorded on video and described for the first time. Upon contact of two individuals, the anterior adhesive discs of the donor firmly attached to the dorsal tegument of the recipient and the donor's fore body strongly contracted such that the genital pore region protruded and the penis was pushed anteriorly to protrude through the genital pore. It is hypothesised that the donor penis mechanically damaged the tegument of the recipient. The sperm and spermatophore matrix were released together through the penis, which was placed under the left anterior attachment disc immediately behind the adhesive pad. The spermatophore matrix containing the spermatozoa became solid and attached to the dorsal surface of recipient's body. When observed under scanning electron microscopy, the spermatophores were irregularly shaped, with a diameter of 52–83 μm. Under light microscopy they consisted of a proximal eosinophilic matrix portion and a distal thin-walled portion containing spermatozoa. Both parts were enclosed with a thin outer casing. Insemination occurred during and after spermatophore formation. Three types of insemination were recorded, unilateral and mutual insemination and self-insemination. The presence of self-insemination indicates that even a single N. girellae on a cultured fish may cause a significant parasite infection in the entire aquaculture system.     

Peptidomics of the pars intercerebralis-corpus cardiacum complex of the migratory locust, Locusta migratoria.

The pars intercerebralis-corpora cardiaca system (PI-CC) of insects is the endocrinological equivalent of the hypothalamus-pituitary system of vertebrates. Peptide profiles of the pars intercerebralis and the corpora cardiaca were characterized using simple sampling protocols in combination with MALDI-TOF and electrospray ionization double quadrupole time of flight (ESI-Qq-TOF) mass spectrometric technologies. The results were compared with earlier results of conventional sequencing methods and immunocytochemical methods. In addition to many known peptides, several m/z signals corresponding to putative novel peptides were observed in the corpora cardiaca and/or pars intercerebralis. Furthermore, for a number of peptides evidence was provided about their localization and MALDI-TOF analysis of the released material from the corpora cardiaca yielded information on the hormonal status of particular brain peptides.     

Embryonic development of the pars intercerebralis/central complex of the grasshopper

 We have studied the embryonic development of the pars intercerebralis/central complex in the brain of the grasshopper using immunocytochemical and histochemical techniques. Expression of the cell-surface antigen lachesin reveals that the neuroblasts of the pars intercerebralis first differentiate from the neuroectoderm at around 26% of embryogenesis. Differentiation of medial and lateral neuroblasts occurs first. By the 28% stage a more or less uniform sheet of 20 neuroblasts has formed. As a result of both cell proliferation and cell translocation, the pars intercerebralis proliferative cluster in each hemisphere expands so that at 30% the most medial neuroblasts lie apposed at the midline. We followed the further development of the pars intercerebralis of each brain hemisphere using bromo-deoxy-uridine incorporation and osmium-ethyl-gallate staining. Within the pars intercerebralis itself, the neuroblasts redistribute into discrete subsets. The neuroblasts of each subset generate clusters of progeny which extend in a stereotypic, subset-specific direction in the brain. We have used this feature to identify one subset of four neuroblasts as being the likely progenitor cells for four clusters of embryonic neurons (W, X, Y, Z) which develop at around 55% of embryogenesis. We show that these progeny project axons via four discrete fascicles (w, x, y, z) into the embryonic central complex. At the single cell level, Golgi impregnation reveals that the axons from these neighbouring cell clusters remain discrete, and those from the same cluster tightly fasciculated, as they project into the central complex, consistent with a modular organization for this brain region. Received: 16 June 1997 / Accepted: 25 June 1997     

Role of arginase transferred from the vesicula seminalis during mating and changes in amino acid pools of the spermatophore after ejaculation in the silkworm,Bombyx mori

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• 1.1. Ejaculation of seminal fluid into the spermatophore formed inside the female bursa copulatrix terminates 20 min after the beginning of copulation of Bombyx mori. The amounts of amino acids transferred are small, but the amounts of amino acids in the spermatophore continue to increase after this time due to protein degradation and amino acid interconversions.
• 2.2. Arginase, which has high activity in the vesicula seminalis, is transferred to the spermatophore without loss of activity during ejaculation. During mating, ornithine and much urea are formed in the spermatophore, indicating activity of the transferred arginase.
• 3.3. In the spermatophore, marked increase of alanine with low concentrations of ornithine and glutamate suggests the presence of a pathway for the active formation of 2-oxoglutarate with pyruvate via glutamate from arginine. During mating, proline and glutamine also increase, but at low rates.
• 4.4. Of the exocrine glands in the male reproductive system, the vesicula seminalis secretes the highest concentration of glutamate (30% of the total amino acids); serine is the amino acid present at highest concentration in secretions of other glands (20–30%). No urea was found in the secretions of any of the glands.

     

Signaling or Not-Signaling: Variation in Vulnerability and Defense Tactics of Armored Ground Crickets (Acanthoplus Speiseri: Orthoptera, Tettigoniidae, Hetrodinae)

Male Orthoptera singing from exposed perches are at risk from acoustically- and visually-hunting predators. The defensive reactions of armored ground crickets (Acanthoplus speiseri) include falling silent, dropping from their perch, alarm stridulation and autohaemorrhaging. Male and female ground crickets show different reactivity (i.e. the number or intensity of defense tactics used) to predation, depending on level of exposure: calling males were more reactive when approached during daylight, compared with in the dark. During daylight, calling males were more reactive than silent, cryptic, males and females. The level of response presumably reflected the riskiness of the individual’s behavior and situation at that time. Plasticity of response to predation allows individuals to balance risky behavior (i.e. acoustic signaling from exposed perches) by being more reactive to potential threats.     

Descending stridulatory interneurons in the suboesophageal ganglion of two grasshopper species

1. The activity of interneurons in the suboesophageal ganglion of the acridid grasshoppers Omocestus viridulus (L.) and Chorthippus mollis (Charp.), recorded intracellularly during stridulation, was found to conform to the rhythm of the singing movements. The arborizations of these neurons in this ganglion are largely bilaterally symmetrical; the axon descends contralaterally to the soma and passes at least into the metathoracic ganglion.
2. The anatomical and physiological characteristics of these neurons are similar in the two species and of four types. Three of them exhibit a tonic, spontaneous activity in the resting animal, which is modulated in the stridulatory rhythm as soon as singing begins. The fourth type has no resting activity and discharges only during the song, in a stridulation-specific pattern.
3. By transecting the connectives it was shown that the rhythmic activity of the neurons is not determined by input from the brain, nor is it generated in the suboesophageal ganglion itself. It is based on information about the song pattern that ascends from the thoracic ganglia.

     

Courtship and mating in the whip spider Phrynichus orientalis Weygoldt, 1998 (Chelicerata: Amblypygi)

Mating behaviour and spermatophore morphology of the south-east Asian whip spider Phrynichus orientalis is described. During courtship there is less bodily contact between mates than in other studied species of the same genus. However, a peculiarity for the species is that the pair often pauses for minutes, sitting front to front without any movement. For spermatophore formation, the male shifts his body under that of the female like in many other species. However, after spermatophore formation, the male lures the female to the spermatophore instead of pulling her as in most other species studied. The spermatophore differs from those of most other species of the genus by the fact that the cushions in front of the sperm masses are replaced by a hard, transparent mass which has the same function as the cushions. Mating behaviour and spermatophore morphology of P. orientalis thus show peculiarities that so far have not been described for other species of the genus. It is not clear whether these characters should be considered plesiomorphic or apomorphic. But it does clearly show that there is more diversity within this genus than expected.     

Moulting and ecdysone release in response to electrical stimulation of protocerebral neurosecretory cells in Locusta migratoria

Locusta migratoria larvae were submitted to electrical stimulation of the protocerebral neurosecretory cells (median neurosecretory cells of the pars intercerebralis and lateral neurosecretory cells), during the last larval instar. The effects of the treatment were observed both on the duration of the stage and on the variations in haemolymph ecdysone levels. In untreated larvae, there was an initial ecdysone peak at the beginning of day 5, which was followed by 4 larger peaks between days 6 and 8. Stimulation of the median neurosecretory cells at the beginning of the instar resulted in the formation of one very large hormonal peak at the end of day 3: a day and a half earlier than in the control groups. Moulting was likewise accelerated. Stimulation also increased the size of the peaks, as compared with the controls. Stimulation of the lateral neurosecretory cells had a weaker ecdysiotropic effect; neither the number nor the size of the peaks were changed, though, like ecdysis, they occurred earlier. Stimulation of the deutocerebrum had no effect on either ecdysone titres or moulting. Electrical stimulation of the median neurosecretory cells at the end of day 5, that is after the occurrence of the first ecdysone peak, shortened the larval stage while having no significant effect on ecdysone levels in the haemolymph. The neuroendocrine control of ecdysis in Locusta is discussed.     

Chilling affects allatal cell proliferation via antennae and protocerebral neurons in the cockroach Diploptera punctata

The corpora allata (CA) cells in a mated female of the cockroach Diploptera punctata undergo numerous mitotic divisions before an increase in juvenile hormone synthesis. A previous study demonstrated that this mitotic wave could be suppressed by exposure of the mated female to melting ice. Herein, we report that chilling suppresses CA mitosis via antennal perception. Cell proliferation-suppressing stimuli from chilling were acquired in proportion to the length of time of exposure to the low temperature and the physical length of the antennae exposed to chilling. Sixty basal antennal annuli should remain exposed to chilling for at least 1.5 h in order to suppress mitotic divisions in CA. Mitotic divisions in corpus allatum are suppressed by stimuli from contralateral antenna, predominantly via pars intercerebralis neurons. Selective disconnection of pars intercerebralis neurons from CA, prior to chilling, restored the mitotic wave in CA. Cellular divisions did not occur in CA of chilled females if either pars lateralis neurons were severed or left intact.