Active regulation of respiration and circulation in pupae of the codling moth (Cydia pomonella)

Regulation of autonomic physiological functions has been investigated by means of multisensor electronic methods, including electrocardiographic recording of heartbeat, strain-gauge recording of extracardiac hemocoelic pulsations (EHPs), anemometric recording of air passage through spiracles and respirographic recording of O(2) consumption and CO(2) output. Pupae of Cydia exhibit continuous respiration without remarkable bursts of CO(2). The dorsal vessel of these pupae exhibited regular heartbeat reversals characterized by shorter intervals of faster (forward oriented or anterograde) pulsations and longer intervals of slower (backward oriented or retrograde) peristaltic waves. The periodically repeated EHPs were present during the whole pupal interecdysial period. The internal physiological mechanisms regulating the cardiac (heartbeat) and extracardiac (EHP) pulsations were completely independent for most of the pupal instar. Simultaneous multisensor analysis revealed that the anterograde heartbeat of the dorsal vessel had similar but not identical frequency with EHPs. During advanced pharate adult development, frequency of cardiac and extracardiac pulsation periods profoundly increased until almost uninterrupted pulsation activity towards adult eclosion. At this time, the cardiac and extracardiac pulsations occasionally performed in concert, which enhanced considerably the efficacy of hemolymph circulation in pharate adults with high metabolic rates. The fastest hemolymph flow through the main body cavity was always associated with EHPs and with anterograde heartbeat. Simple physical diffusion of O(2) and CO(2) through spiracles (diffusion theory of insect respiration) does not play a significant role in pupal respiration. Instead, several kinds of regulated, mechanical ventilations of the tracheal system, including EHPs are responsible for effective tracheal ventilation.     

A new look at the comparative physiology of insect and human hearts

Recent electrocardiographic (ECG) studies of insect hearts revealed the presence of human-like, involuntary and purely myogenic hearts. Certain insects, like a small light-weight species of hoverfly (Episyrphus balteatus), have evolved a very efficient cardiac system comprised of a compact heart ventricle and a narrow tube of aorta, which evolved as an adaptation to sustained hovering flights. Application of thermocardiographic and optocardiographic ECG methods revealed that adult flies of this species use the compact muscular heart chamber (heart ventricle) for intensive pumping of insect "blood" (haemolymph) into the head and thorax which is ringed all over with indirect flight musculature. The recordings of these hearts revealed extremely high, record rates of forward-directed, anterograde heartbeat (up to 10Hz), associated with extremely enhanced synchronic (not peristaltic) propagation of systolic myocardial contractions (32.2mm/s at room temperature). The relatively slow, backward-directed or retrograde cardiac contractions occurred only sporadically in the form of individual or twinned pulses replacing occasionally the resting periods. The compact heart ventricle contained bi-directional lateral apertures, whose opening and closure diverted the intracardiac anterograde "blood" streams between the abdominal haemocoelic cavity and the aortan artery, respectively. The visceral organs of this flying machine (crop, midgut) exhibited myogenic, extracardiac peristaltic pulsations similar to heartbeat, including the periodically reversed forward and backward direction of the peristaltic waves. The tubular crop contracted with a periodicity of 1Hz, both forwards and backwards, with propagation of the peristaltic waves at 4.4mm/s. The air-inflated and blindly ended midgut contracted at 0.2Hz, with a 0.9mm/s propagation of the peristaltic contraction waves. The neurogenic system of extracardiac haemocoelic pulsations, widely engaged in the regulation of circulatory and respiratory functions in other insect species, has been replaced here by a more economic, myogenic pulsation of the visceral organs as a light-weight evolutionary adaptation to prolonged hovering flight. Striking structural, functional and even genetic similarities found between the hearts of Episyrphus, Drosophila and human hearts, have been practically utilised for inexpensive testing of new cardioactive or cardioinhibitory drugs on insect heart.     

Delayed pharmacological effects of proctolin and CCAP on heartbeat in pupae of the tobacco hornworm, Manduca sexta

Abstract. The effects in vivo of cardioactive peptides proctolin, CCAP and leucomyosuppressin (LMS) are investigated by means of noninvasive optocardiographic or thermographic techniques in postdiapause pupae of Manduca sexta. A constant pattern of heartbeat reversal in these pupae is manifested by regular alternations of the forward orientated (anterograde) and the backward orientated (retrograde) cardiac pulsations, with a periodicity of some 5–10 min. The heartbeat pattern is monitored continuously for several hours before and 24 h after injection of the investigated peptides. Injections of Ringer solution alone cause a slight, almost immediate increase of the rate of the pupal heartbeat (0–10%), which lasts only for 20–30 min. Injection of proctolin, CCAP or LMS does not show any immediate cardiostimulating effects (beyond those of Ringer) at concentrations up to 2 × 10⁻⁶ M (calculated from µg of the injected peptide and 70% pupal water content; 5–7 g pupal body mass). By contrast, injections of proctolin and CCAP in the range of 10^-9 − 10^-6 M concentrations cause delayed effects on the heartbeat, which are manifested only several hours after the injections. The delayed effects involve prolonged, or even continuous periods of unidirectional, more efficient and faster anterograde pulsations. Consequently, the flow of haemolymph through the head and thoracic parts of the pupal body increases. In the case of proctolin, the prolonged anterograde cardiac activity usually starts 5 h after the injections and the effect persists for 7–12 h. Using CCAP, the stimulation of anterograde activity starts 2.5–3 h after injections and lasts usually 7–8 h. Very small doses of peptides (10^-8 − 10^-9 M) do not change the latency period significantly, but they decrease the duration of the response. The frequency of the systolic contractions of the heart does not increase during the prolonged anterograde phase. Injections of LMS to produce a final concentration of 10⁻⁶ M in the pupa induce pathophysiological disturbances of heartbeat reversal and peristalsis. The effects start with a delay of some 1.5–2.5 h after the injections. By contrast to the effects of proctolin and CCAP, LMS does not produce delayed anterograde cardiac pulsations. These results show that the most intensively investigated cardiostimulating peptides in vitro, proctolin and CCAP, have no direct cardiostimulating activity under physiological conditions in vivo. It is concluded therefore that the delayed pharmacological effects of these peptides observed in the pupae of M. sexta, represent a secondary effect, resulting from stimulation of nonspecific, extracardiac myotropic or other physiological functions.     

Heartbeat patterns during the postembryonic development of Drosophila melanogaster

Pulsations of the dorsal vessel were recorded in vivo during the whole postembryonic development of D. melanogaster, by means of a newly invented, pulse-light opto-cardiographic method. The young larvae of the 1st and 2nd instars submerged in the feeding medium exhibited extremely high rates of heartbeat, 7Hz at room temperature. These values are among the highest rates of heartbeat ever recorded in the animal kingdom. The fully grown larvae of the 3rd instar showed approximately half of the maximum heartbeat rate (3.5-4Hz), which became stabilized after pupariation to 2.5-2.7Hz.The larval heartbeat was always uni-directional, in the forward-oriented or anterograde direction and it was almost continuous. The slowly disintegrating, old larval heart used to beat at the constant frequency of 2.5-2.7Hz until complete cessation of all cardiac functions in 1-day-old puparium. In spite of the persisting constant heartbeat frequency, the transformation process of the larval heart was associated with successively decreasing amplitude of the systolic contractions and with the prolongation of the resting periods. The newly formed heart of the pupal-adult structure exhibited a qualitatively new pattern of heartbeat activity, which was manifested by periodic reversal of the heartbeat with the faster anterograde and slower retrograde phases. The frequencies of both of these reciprocal cardiac pulsations gradually increased during the advanced pharate adult period, reaching the values of 4-5Hz at the time of adult eclosion. Adult males and females also exhibited a perfect pattern of heartbeat reversal, with still very high rates of the anterograde heartbeat, in the range of 5-6Hz. In addition to the cardiac functions, we have recorded several kinds of extracardiac pulsations, which often interfered severely with the recordings of the heartbeat. There were strong, irregular extracardiac pulsations of a neurogenic nature (somatic muscles, oral armature) and relatively slow extracardiac pulsations of a myogenic nature (intestinal peristaltics, 0.2-0.3Hz). The extracardiac and cardiac pulsations were independent, their functions were not correlated. A possibility of creating new challenges in combination of molecular biology with the functional physiology of the heart have been discussed.     

Co-ordination of firing activity of neurosecretory cells with cardiac activity in the silkmoth Bombyx mori

Electrocardiograms and electrical action potentials of cerebral neurosecretory cells producing bombyxin (an insulin-related neuropeptide) were simultaneously recorded from male pupae of the silkmoth Bombyx mori. A pupa showed alternations in the flow of haemolymph due to a rhythmic heartbeat reversal: a train of retrograde heartbeat with a slow pulse rate followed a train of anterograde heartbeat with a higher pulse rate. Intervals of heartbeat reversals changed throughout the pupal period. At any stage of the pupal period, firing activity of a population of bombyxin-producing (BP) cells rapidly declined after the start of anterograde heartbeat and an inactive state of cells continued during an anterograde heartbeat period. Analyses of ultradian bursting rhythmicity of a single BP cell revealed that a bursting phase of the cell often delayed at a time when the anterograde cardiac activity occurred at the preceding inter-burst period of firing rhythm. The results support the postulation that firing (secretory) activity of an insect neurosecretory cell system may be co-ordinated with circulation of haemolymph for rapid and pulsatile delivery of the peptides released to target organs.     

Control of extracardiac haemolymph pressure pulses in Tenebrio molitor

The pupae of Tenebrio exhibit periodic pulsations in the haemolymph pressure which are independent of the heartbeat. Tensometric records of the extracardiac pulses show certain specific modifications caused by changes in either the internal or external environment. Chronological changes in the pulse pattern were associated with adult morphogenesis and ecdysis. The abdominal pump controlling extracardiac pressure pulsations is independent of the brain or of any other cephalic part of the nervous system. The nerve impulses controlling the pump arise only in the mesothoracic ganglion. They are carried by the connectives to certain abdominal ganglia from which they are further transmitted to the contracting intersegmental abdominal muscles. The extracardiac pulses in haemolymph pressure aid in the maintenance of water balance and respiration and assist with the circulation of haemolymph through the appendages.     

Mechanical aspects of heartbeat reversal in pupae of Manduca sexta

Pulsations of the dorsal vessel were investigated with new optocardiographic techniques based on the transmission and reflection of pulse-light through optic fibers. This noninvasive technique enabled simultaneous, in vivo multisensor recordings of the heartbeat without touching the pupal integument. There was a very regular heartbeat reversal with 3 distinctive phases: (a) a backward-oriented (retrograde) cardiac pulsation; (b) a forward-oriented (anterograde) pulsation with faster frequency; and (c) shorter or longer periods of temporary cardiac standstill that usually occurred after the termination of the anterograde phase. Occasionally, there were localized series of systolic cardiac contractions during the retrograde phase. Simultaneous recordings from the base and the tail of the abdomen revealed a reciprocal, "mirror image-like", quantitative relationship. The most intensive anterograde hemolymph flow occurred at the base while the most intensive retrograde flow occurred at the tail of the abdomen. The bi-directional switchovers of heartbeat (reversal) were occasionally associated with modifications during each of the unidirectional cardiac phases. Anterograde peristalsis showed a 2-fold higher frequency of pulsation in the thoracic aorta in comparison with the posterior parts of the heart. Thus, in addition to the "odd" peristaltic waves originating at the tail, there were intercallated "even" peristaltic waves originating in the middle of the abdomen. Both of them propagated hemolymph through the thoracic aorta into the head; the first waves took the hemolymph in from the distal end, while the second sucked it from the middle of the abdomen. The use of multiple optocardiographic sensors also enabled detection of cardiac pulsations on the opposite, ventral side of the body, within the ventral perineural sinus. The ventral side of the head showed only the presence of an anterograde pulse, whereas the ventral side of the tail exhibited a strong reciprocal retrograde phase and a very weak anterograde phase. These results explain why the existence of a periodic heartbeat reversal should be essential for circulatory functions at both extremities of the cylindrical insect body. In diapausing pupae, regular cycles of heartbeat reversal were substituted by prolonged periods of anterograde pulsation during the entire duration of bursts of CO2 release (average duration of the burst was 18-20 min, periodicity 5 to 18 h). The physiological nature of such feed-back correlation between heartbeat and metabolic CO2 production is not yet clear, because the anterograde heartbeat could be also induced by a number of nonspecific factors unrelated to CO2 (mechanical irritation, injury, injections, elevated temperature). During the postdiapause, developing pharate-adult stage, the correlation between CO2 and anterograde heartbeat completely disappeared. It has been concluded that regulation of insect heartbeat represents a highly coordinated, myogenic stereotype with inherent rhythmicity, which can be modified by a number of external and internal factors.     

The effects of 20-hydroxyecdysone on haemolymph pressure pulsations in Tenebrio molitor

Changes in haemocoelic pressure have been studied after the injection of exogenous 20-hydroxyecdysone, using a special tensometric method. Application of the hormone before the endogenous peak of ecdysteroid causes an acceleration of the progressive changes in the pulsation pattern. When given during the endogenous ecdysteroid peak, 20-hydroxyecdysone produces a retention of the existing type of pulsation. Also, administration of the hormone after the endogenous peak induces a retardation in the developmental programme of the pulsations. Shortly before ecdysis, the exogenous hormone does not affect the pulsation programme or the ecdysis. These changes may represent an elegant example of a homeostatic function of ecdysteroids in insect development. Involvement of 20-hydroxyecdysone in regulation of the basic haemolymph pressure is discussed.     

Myogenic nature of insect heartbeat and intestinal peristalsis, revealed by neuromuscular paralysis caused by the sting of a braconid wasp

Larvae of the greater waxmoth (Galleria mellonella) become paralysed by the venom of the braconid wasp (Habrobracon hebetor) a few minutes after intoxication. The profound neuromuscular paralysis, which may last for several weeks, includes all somatic muscles that are innervated through neuromuscular transmission. The peristaltic contractions of the heart and intestine, which are regulated by the depolarisation potentials of the myocardium or intestinal epithelial muscles, remain unaffected and fully functional. Heartbeat patterns and intestinal pulsations were monitored in the motionless, paralysed larvae by means of advanced electrocardiographic recording methods (contact thermography, pulse-light optocardiography). The records revealed more or less constant cardiac pulsations characterised by 20-25 systolic contractions per minute. The contractions were peristaltically propagated in the forward (anterograde) direction, with a more or less constant speed of 10 mm per second (23-25 °C). Additional electrocardiographic investigations on larvae immobilised by decapitation revealed the autonomic (brain independent) nature of heartbeat regulation. Sectioning performed in the middle of the heart (4th abdominal segment) seriously impaired the pacemaker rhythmicity and slowed down the rate of heartbeat in the anterior sections. By contrast, the functions of the posterior compartments of the disconnected heart remained unaffected. These results confirmed our previous conclusions about the existence of an autonomic, myogenic, pacemaker nodus in the terminal part of an insect heart. They show an analogy to the similar myogenic, sinoatrial or atrioventricular nodi regulating rhythmicity of the human heart. Peristaltic contractions of the intestine also represent a purely myogenic system, which is fully functional in larvae with complete neuromuscular paralysis. Unlike the constant anterograde direction of the heartbeat, intestinal peristaltic waves periodically reversed anterograde and retrograde directions. A possibility that the functional similarity between insect and human hearts may open new avenues in the field of comparative cardiology has been discussed.     

Rhythms of passive and active ventilation, and circulation recorded in diapausing pupae of Mamestra brassicae using constant volume respirometry

Abstract.  The periodically occurring convective inflow of air into the tracheal system, or passive suction ventilation, together with the cyclic bursts of release of CO₂ and active ventilation, is recorded in diapausing pupae of Mamestra brassicae . A constant volume respirometer combined with an opto-cardiograph-actograph is used. In all pupae with a metabolic rate of 0.025–0.054 mL g⁻¹ h⁻¹, the bouts of almost imperceptible abdominal contractions are recorded during the bursts of carbon dioxide release and this mode of active ventilation is qualified as extracardiac haemocoelic pulsations. The pupae whose metabolic rate is 0.052–0.075 mL⁻¹ g⁻¹ h⁻¹ show more vigorous abdominal contractions. The results demonstrate that, in diapausing pupae, characterized with low metabolic rates, both passive suction ventilation, referred to also as passive suction inspiration, and active ventilation occurs. In approximately 50% of the pupae, each gas exchange microcycle during the interburst periods begins with a miniature PSI followed by a microburst of CO₂ release; in approximately 30% of the individuals, passive suction inspirations occur separately from CO₂ microbursts; in the remaining pupae, miniature ones without microbursts of CO₂ are recorded. A typical event is heartbeat reversion: in longer periods, the heart peristalses are directed forward (anterograde of heartbeat) and, in shorter periods, the heart peristalses are directed backward (retrograde of heartbeat). At 0 °C, the cyclic release of CO₂ and miniature passive suction inspirations during the interburst periods are preserved at lower frequencies but active ventilation is lost.     

Biogenic amines evoke heartbeat reversal in larvae of the sweet potato hornworm,Agrius convolvuli

The sweet potato hornworm, Agrius convolvuli, possesses a pair of anterior cardiac nerves innervating the dorsal vessel. The anterior cardiac nerves branch off the visceral nerve that arises posteriorly from the frontal ganglion. Heartbeat reversal from anterograde heartbeat to posterograde heartbeat is triggered by the anterior cardiac nerves. Application of octopamine (OA) during the anterograde heartbeat phase reverses the anterograde heartbeat to the posterograde heartbeat, while application of OA during the phase of posterograde heartbeat accelerates heartbeat. The heartbeat reversal from anterograde heartbeat to posterograde heartbeat evoked by stimuli applied to the visceral nerve is blocked by application of the octopaminergic antagonists, phentolamine and chlorpromazine. The results suggest that OA may be a neurotransmitter for the anterior cardiac nerve. The alary muscle of the second segment receives excitatory innervation from the posterior cardiac nerve and from the nerve which extends from the second abdominal ganglion. Activation of the alary muscle results in acceleration of posterograde heartbeat. Other neurotransmitters, besides OA, may take part in the resultant acceleration.     

Roles of aorta,ostia and tracheae in heartbeat and respiratory gas exchange in pupae of Troides rhadamantus Staudinger 1888 and Ornithoptera priamus L. 1758 (Lepidoptera,Papilionidae)

In non-diapausing pupae of the two birdwing butterfly species Troides rhadamantus and Ornithoptera priamus (Lepidoptera, Papilionidae) heart activity and CO₂ release rates were measured simultaneously within the initial half of pupal development. Heartbeat patterns in these pupae consist of three different types of activity: Continuous forward-pulse periods of different duration with a frequency range of about 0.25–0.52 s⁻¹, continuous backward-pulse periods with lower frequencies (0.15–0.29 s⁻¹) and intermittent backward-pulse periods when short series of three to 10 single heartbeats at frequencies of 0.12–0.35 s⁻¹ alternated with heart pauses of 2–10 min. CO₂ release was discontinuous (CFO-type) from about four to 12 days after pupation in Troides rhadamantus and from about four to 18 days in Ornithoptera priamus. Mean CO₂ release rates were very low in both species (10–30 nmol g⁻¹ min⁻¹). After this period, heart pauses occurred more frequently, probably indicating the onset of metamorphosis and the beginning partial histolysis of the heart. Infrared-optical and thermometrical measurements of heartbeat indicated that haemolymph transport within the dorsal vessel in forward direction is more effective than in backward direction. This is deduced from the higher heartbeat frequency and heartbeat amplitude of the forward pulsations. Results from ultrasonic doppler velocimetry suggest that haemolymph flow velocity is highest during the relatively long diastasis of 2–3 s (30–40 mm s⁻¹), while minimum particle speed (about 20 mm s⁻¹) is at the end of systole and the beginning of diastole. This would mean that haemolymph velocity is highest between two consecutive peristaltic waves. In contrast to the haemolymph velocity, the speed of the peristaltic wave measured with the infrared transmission technique was lower (about 8.4–22 mm s⁻¹ in Troides, 10–23 mm s⁻¹ in Ornithoptera) and remained constant during forward pulse periods. During backward beating the speed was lower (8–20 mm s⁻¹ in Troides, 9–17 mm s⁻¹ in Ornithoptera) and decreased during backward pulse periods. During day two to seven in Troides and day three to nine in Ornithoptera, spiracular opening periods coincided with changes in heartbeat direction from backward to forward pulsations. A possible influence is the more efficient convective haemolymph mixing in the haemocoel during forward heartbeat. The mixing allows to bring the haemolymph in close contact with the tracheal system where the discharge of CO₂ takes place. Heartbeat may therefore serve for shortening the diffusion pathways for a rapid transition into the tracheal system during the open period of the spiracles.     

Rhythmic firing activity of median neurosecretory cells of the subesophageal ganglion and its coordination with periodically occurring abdominal movements in the tenebrionid [corrected] beetle, Zophobas atratus [corrected

An immunocytochemical study using an FXPRLamide antiserum revealed three clusters of neurosecretory cells along the midline of the subesophageal ganglion of the tenebrionid [corrected] beetle, Zophobas atratus [corrected] Firing activity of five pairs of neurosecretory cells in the mandibular and maxillary clusters was recorded from an axonal tract of the cells throughout the entire pupal period. The population of neurosecretory cells became active during the middle and late pupal periods, and they usually discharged clusters of action potentials at an interval of 30-90 min. The ultradian activity rhythm of the cells in Z. atratus [corrected] was related to a periodic discharge of electrical activity in developing flight muscles, as has been observed in the homologous cells in the silkmoth, Bombyx mori. Furthermore, the rhythmic activity of the neurosecretory cells in the mealworm was closely synchronized with periodically occurring rhythmic abdominal movements that caused extracardiac hemocoelic pulsations, which facilitate hemolymph circulation and exchange of respiratory gases. The results suggest that the secretory products of the neurosecretory cells may activate and/or orchestrate physiological mechanisms supporting morphogenesis during metamorphosis.     

Abdominal movements, heartbeats and gas exchange in pupae of the Colorado potato beetle, Leptinotarsa decemlineata

The rhythms of abdominal movements, heartbeats and gas exchange in the pupae of Leptiontarsa decemlineata (Say) were recorded simultaneously using an electrolytic respirometer and infrared gas analyser, both combined with contact thermography. Abdominal pulsations and heartbeat occurred periodically with little variance among individuals. The abdominal pulsations and heartbeat pauses varied individually within large limits, with the frequency of abdominal pulsations being six to seven times lower than that of the heart pulses. A proportion of the pupae (20%) showed discontinuous gas exchange with large, actively ventilated CO₂ bursts, whereas others (≈ 25%) exhibited continuous regular microcycles (flutter) with abrupt intake of air into the tracheae before discrete microbursts of carbon dioxide. The abdominal pulsations exerted only a minor influence on ventilation during the microcycles. More than 90% of the bursts of abdominal movement coincided with a series of forward directed heartbeats, but interspersed between the bouts of abdominal movement commonly two to three heartbeat pulses were observed that were not associated with abdominal movements. A period of abdominal movement associated with a heartbeat pulse was commonly initiated by one or two vigorous strokes of abdominal rotation.     

Contraction of the ventral abdomen potentiates extracardiac retrograde hemolymph propulsion in the mosquito hemocoel

Background

Hemolymph circulation in mosquitoes is primarily controlled by the contractile action of a dorsal vessel that runs underneath the dorsal midline and is subdivided into a thoracic aorta and an abdominal heart. Wave-like peristaltic contractions of the heart alternate in propelling hemolymph in anterograde and retrograde directions, where it empties into the hemocoel at the terminal ends of the insect. During our analyses of hemolymph propulsion in Anopheles gambiae, we observed periodic ventral abdominal contractions and hypothesized that they promote extracardiac hemolymph circulation in the abdominal hemocoel.

Methodology/Principal Findings

We devised methods to simultaneously analyze both heart and abdominal contractions, as well as to measure hemolymph flow in the abdominal hemocoel. Qualitative and quantitative analyses revealed that ventral abdominal contractions occur as series of bursts that propagate in the retrograde direction. Periods of ventral abdominal contraction begin only during periods of anterograde heart contraction and end immediately following a heartbeat directional reversal, suggesting that ventral abdominal contractions function to propel extracardiac hemolymph in the retrograde direction. To test this functional role, fluorescent microspheres were intrathoracically injected and their trajectory tracked throughout the hemocoel. Quantitative measurements of microsphere movement in extracardiac regions of the abdominal cavity showed that during periods of abdominal contractions hemolymph flows in dorsal and retrograde directions at a higher velocity and with greater acceleration than during periods of abdominal rest. Histochemical staining of the abdominal musculature then revealed that ventral abdominal contractions result from the contraction of intrasegmental lateral muscle fibers, intersegmental ventral muscle bands, and the ventral transverse muscles that form the ventral diaphragm.

Conclusions/Significance

These data show that abdominal contractions potentiate extracardiac retrograde hemolymph propulsion in the abdominal hemocoel during periods of anterograde heart flow.     

The permeability of the midgut of three insects to cardiac glycosides

The uptake of a polar and nonpolar cardiac glycoside by three insects, Oncopeltus fasciatus, Schistocerca gregaria and Periplaneta americana was investigated. Of these insects, the midgut of only O. fasciatus was found to be permeable to cardiac glycosides. Ouabain was not metabolized by this insect and crossed the midgut slowly and passively. It was sequestered from the haemolymph into the dorsolateral spaces against a concentration gradient and at relatively fast rates suggesting that uptake from the gut is rate limiting. Digitoxin was metabolized at the level of the midgut but not in the isolated haemolymph or dorsolateral space fluids. Twenty-four hours after feeding O. fasciatus labelled digioxin, digitoxin metabolites but no unchanged digitoxin could be detected in the haemolymph while both metabolites and a small amount of unchanged digitoxin could be detected in the dorsolateral space fluids.     

Regulation of insect prothoracic glands: Existence of a haemolymph stimulatory factor in Manduca sexta

The primary regulator of ecdysone biosynthesis by insect prothoracic glands is the prothoracicotropic hormone. However, it now appears that other factors, secondary regulators, may modulate prothoracic gland activity. One such factor has been isolated from the haemolymph of Manduca larvae. This haemolymph factor stimulates in vitro ecdysone synthesis by larval and pupal prothoracic glands by approx. 5-fold. It has an apparent mol. wt of ～330 kD, is protease-sensitive and is heat labile, the latter clearly distinguishing it from the prothoracicotropic hormone. Further, its steroidogenic effects and those of prothoracicotropic hormone are additive. Treatment of larval or pupal prothoracic glands with both moieties simultaneously effects an approx. 10-fold increase in ecdysone synthesis. The haemolymph titre of the stimulatory factor is low at commitment of the last-larval instar, then increases by approx. 3-fold later in the instar during pharate-pupal development. This increase in the titre is sufficient to effect a significant increase in prothoracic gland activity that could be physiologically important. Thus, it appears that the fluctuating level of this haemolymph stimulatory factor may act in conjunction with prothoracicotropic hormone to regulate the haemolymph ecdysteroid titre by modulating the ecdysone biosynthetic activity of the prothoracic glands.     

Changes taking place in the electrophoretic haemolymph protein pattern during metamorphosis of Polytela gloriosae (Lepidoptera)

The haemolymph proteins of the larva, pupa and adult of Polytela gloriosae have been fractioned by Polyacrylamide gel disc electrophoresis. In the haemolymph of the fifth instar larval stage a total of ten protein fractions have been detected. The concentration of the protein fractions 2, 3, 4, 9 and 10 shows oscillations in their concentration in the early fifth instar, middle fifth instar and late fifth instar larval stage. In all 11 protein fractionswere detected in the haemolymph of different stages of the pupa. The protein bands 1, 7 and 10 of the pupa appear newly in the haemolymph as these bands were not found in the haemolymph of the larvae. The protein fraction 9 of larva was not found in the pupa. In the haemolymph of adult insect sexual difference was observed in the haemolymph protein pattern. In the haemolymph of adult female a total of 10 protein fractions were detected while from the male haemolymph a total of 8 protein fractions were detected. The pupal band 7 was not found in the adults of both the sexes. In the haemolymph of larva and adult one pigmented protein fraction was observed. No pigmented protein fraction was found in the haemolymph of pupa. Iron - containing protein fraction and the acid mucopolysaccharides were not found in the haemolymph. The protein fractions 3, 4, 5, 6 and 7 of adult haemolymph were darkly stained by the Schiff reagent and, thus, they are the fractions of glycoprotein. One protein fraction of lipoprotein was also found in the haemolymph.     

Peptidergic modulation of cardiovascular dynamics in the Dungeness crab,Cancer magister

Decapod crustacean pericardial organs contain extensive neurohormonal reserves which can be released directly into the haemolymph to act as physiological modulators. The present paper concerns the in vivo effects of two pericardial peptides, proctolin and crustacean cardioactive peptide, on cardiovascular dynamics in the crab Cancer magister. Infusion of proctolin into the pericardial sinus caused a slight decrease in heart rate concurrent with a large increase in cardiac stroke volume. It decreased haemolymph flow anteriorly through the paired anterolateral arteries and increased flow posteriorly and ventrally through the posterior aorta and sternal artery, respectively. The threshold for responses occurred at circulating concentrations of 10^-9 mol·l^-1, and haemolymph flows remained elevated for up to 30 min after peptide infusion. The effects of crustacean cardioactive peptide were less dramatic. Heart rate was not affected but a significant increase in stroke volume was observed. Crustacean cardioactive peptide increased haemolymph flow through the anterolateral arteries and increased scaphognathite rate. The threshold for crustacean cardioactive peptide activity was higher than for proctolin (10^-7 mol·l^-1 and 10^-6 mol·l^-1) but the responses to crustacean cardioactive peptide were of longer duration. The effects of proctolin on regional haemeolymph distribution in Cancer magister closely resemble the cardiovascular responses of this species when exposed to hypoxic conditions. These peptides may be implicated as cardiovascular regulators during environmental perturbations.     

Role of the neuropeptide CCAP in Drosophila cardiac function

The heartbeat of adult Drosophila melanogaster displays two cardiac phases, the anterograde and retrograde beat, which occur in cyclic alternation. Previous work demonstrated that the abdominal heart becomes segmentally innervated during metamorphosis by peripheral neurons that express crustacean cardioactive peptide (CCAP). CCAP has a cardioacceleratory effect when it is applied in vitro. The role of CCAP in adult cardiac function was studied in intact adult flies using targeted cell ablation and RNA interference (RNAi). Optical detection of heart activity showed that targeted ablation of CCAP neurons selectively altered the anterograde beat, without apparently altering the cyclic cardiac reversal. Normal development of the abdominal heart and of the remainder of cardiac innervation in flies lacking CCAP neurons was confirmed by immunocytochemistry. Thus, in addition to its important role in ecdysis behavior (the behavior used by insects to shed the remains of the old cuticle at the end of the molt), CCAP may control the level of activity of the anterograde cardiac pacemaker in the adult fly. Expression of double stranded CCAP RNA in the CCAP neurons (targeted CCAP RNAi) caused a significant reduction in CCAP expression. However, this reduction was not sufficient to compromise CCAP's function in ecdysis behavior and heartbeat regulation.