Myoelectric response of the small intestine to the orad presence of the tapeworm Hymenolepis diminuta.

During its 24-hr migratory cycle in the small intestine, Hymenolepis diminuta is located in the orad part of the small intestine during the early morning hours and then in the caudad part of the small intestine during the late afternoon and early evening. During the later period, tapeworm-induced alterations of interdigestive myoelectric activity, a correlate of smooth muscle contraction or intestinal motility, are most intense in the ileal region. The hypothesis tested was that the tapeworm-induced changes in intestinal motility are local responses of the intestine responding to the close proximity of the lumenally positioned tapeworm and to the nutritional state of the host. The small intestine was monitored before and for 20 days after infection using electrodes implanted on the serosa of the small intestine. Myoelectric recordings were analyzed for the frequency of the normal patterns of interdigestive myoelectric spiking patterns and the altered myoelectric spiking related to tapeworm infection. During the morning hours, when the tapeworms are situated in the orad small intestine, no changes were observed during the normal myoelectric pattern of the digestive phase in any region of the intestine. When examined after the conversion of the digestive to interdigestive phase of motility, only on day 10 postinfection was the interdigestive phase significantly altered. It was concluded that the presence of the tapeworm in the orad small intestine during the satiety stage of the rat causes no changes in the electric events of the small intestine, with the exception of day 10 postinfection. Because tapeworms in the orad small intestine do not induce the tapeworm-altered myoelectric activity observed in the afternoon and evening with caudally positioned tapeworms, tapeworm-altered motility is not simply a response of the small intestine to the local presence of the tapeworm.     

Effect of fasting on small intestinal antiperistalsis in the Nicholas turkey (Meleagris gallopavo)

Small intestinal refluxes (SIRs) were monitored in the gastrointestinal tract of Nicholas turkeys via implanted strain gage transducers and radiographic observations. It was determined that reflux of ingesta from the small intestine into the gizzard was a result of a single antiperistaltic contraction. Radiographic observation indicated that the antiperistaltic contraction originated in the ileum 88% of the time and the duodenum 12% of the time. Each antiperistaltic contraction was preceded by a single peristaltic contraction. No gastric contractions occurred during SIRs. Fasting for 12 to 24 hr significantly increased the frequency of occurrence of SIRs in the Nicholas turkey (P < 0.0001) but had no significant effect on the velocity of the peristaltic and antiperistaltic contractions or on recovery time to pre-SIR gastric contractile frequency. The pooled mean velocity of peristaltic contractions was determined to be 10.55 +/- 3.68 cm/sec, and that of antiperistaltic contractions was determined to be 12.12 +/- 3.69 cm/sec. The pooled mean recovery time to pre-SIR gastric contraction frequency was 28.31 +/- 8.25 sec. It has been suggested that the SIR may be a mechanism of maximizing nutrient utilization by the turkey.     

Glycogen synthase in the rat tapeworm, Hymenolepis diminuta--II. Control of enzyme activity by glucose and glycogen.

1. The proportion of activity in the physiologically active I form of glycogen synthase in Hymenolepis diminuta (Cestoda) decreased in the worm when the rat host was fasted and was greatly increased in the cestode 1 hr after a 24 hr fasted rat was refed. 2. The increase in glycogen synthase I activity was due to glucose present in the host gut after feeding, not to other physiological changes in the rat intestine due to meal consumption. 3. Incubation of intact H. diminuta in vitro with glucose also resulted in the conversion of glycogen synthase D to I. 4. Glucose does not appear to affect the glycogen synthase complex directly, because neither the total synthase converted to I nor the rate of conversion was affected by glucose in a partially purified homogenate. 5. High concentrations of glycogen inhibited the synthase D to I conversion and high mol. wt glycogen was a more effective inhibitor than low mol. wt glycogen.     

Effect of surgical alteration of the rat gastrointestinal tract on the growth and development of Hymenolepis diminuta

Eight groups of rats were used to study the involvement of the enteric (ENS) and central (CNS) nervous systems in the development of Hymenolepis diminuta using surgical intestinal transection, or CNS denervation, or both procedures. The transection procedure was used to isolate the ENS of the small intestine from either orad and/or caudal portions of the alimentary system, while the CNS denervation was used to eliminate direct visceral efferent inputs from the CNS. Nine days after the surgical procedures, all rats were infected with 35 cysticercoids of H. diminuta. On 20 days postinfection, the infection intensity, tapeworm dry weight, tapeworm morphology, intestine length, and intestinal wet weight were recorded. Only the combination of the duodenal and ileal transections with a CNS denervation reduced infection intensity and prevented the increased intestinal length normally observed in infected rats. In contrast, none of the various intestinal transection procedures alone or CNS denervation alone had any effect on the survival, ability to produce oncospheres or morphology of the tapeworms. In conclusion, tapeworm survival is decreased when both CNS and ENS inputs into the small intestine are altered or absent.     

Physiological role of neuropeptide Y in the regulation of the ascending phase of the peristaltic reflex

The physiological role of neuropeptide Y (NPY) and of specific NPY receptors in regulating the intestinal peristaltic reflex was examined in three-compartment flat-sheet preparations of rat colon. Graded muscle stretch or mucosal stimulation applied to the central compartment inhibited NPY release in the orad compartment where ascending contraction was measured. NPY and the Y1-receptor agonist [Leu31, Pro34]NPY inhibited, whereas the selective Y1-receptor antagonist BIBP 3226 augmented ascending contraction and substance P (SP) release in the orad compartment induced by muscle stretch or mucosal stimulation. Neither agonist nor antagonist had any effect on descending relaxation or VIP release in the caudad compartment. The Y2-receptor agonist NPY13-36 and antagonist BIIE 0246 had no effect on peptide release or mechanical response. The results indicate that suppression of a tonic inhibitory influence of NPY neurons on excitatory neurotransmitter release contributes substantially to the orad contractile phase of the peristaltic reflex. The effect of NPY on neurotransmitter release is mediated by Y1 receptors.     

Hymenolepis diminuta: behavioral effects of 5-hydroxytryptamine, acetylcholine, histamine and somatostatin

Consistent in vitro behavioral patterns were found in the scolex and strobila of adult Hymenolepis diminuta. These patterns were measured with a force transducer and the behavior analyzed with a slow motion closed circuit T.V. Varying concentrations of serotonin (5-HT), acetylcholine (Ach), histamine and somatostatin, in the range of 10(-3) to 10(-9) M, were tested for their influence on the rhythmic patterns of behavior. High concentrations of 5-HT and of Ach decreased scolex motility. While 5-HT significantly increased motility in the anterior-, mid- and posterior regions of the strobila at 10(-3) M, Ach inhibited motility in all 3 regions of the strobila at the same concentrations. At high concentrations, somatostatin had a smaller stimulatory effect on worm motility in the anterior and mid-regions; histamine only significantly affected worm motility in the posterior region of the strobila. Depending on concentration, the action of 5-HT, Ach and histamine can be reversed, particularly in the anterior and posterior regions of the strobila. The in vivo assay for worm migrational responses suggests that the action of the neuromuscular stimulators and inhibitors on worm migration is indirect.     

Similarities and differences in the propagation of slow waves and peristaltic waves

The relationship between slow waves and peristaltic reflexes has not been well analyzed. In this study, we have recorded the electrical activity of slow waves together with that generated by spontaneous peristaltic contractions at 240 extracellular sites simultaneously. Recordings were made from five isolated tubular and six sheet segments of feline duodenum superfused in vitro. In all preparations, slow waves propagated as broad wave fronts along the longitudinal axis of the preparation in either the aborad or the orad direction. Electrical potentials recorded during peristalsis (peristaltic waves) also propagated as broad wave fronts in either directions. Peristaltic waves often spontaneously stopped conducting (46%), in contrast to slow waves that never did. Peristaltic waves propagated at a lower velocity than the slow waves (0.98 +/- 0.25 and 1.29 +/- 0.28 cm/s, respectively; P < 0.001; n = 24) and in a direction independent of the preceding slow wave direction (64% in the same direction, 46% in the opposite direction). In conclusion, slow waves and peristaltic waves in the isolated feline duodenum seem to constitute two separate electrical events that may drive two different mechanisms of contraction in the small intestine.     

Spatiotemporal electrical and motility mapping of distension-induced propagating oscillations in the murine small intestine

Since the development of knockout animals, the mouse has become an important model to study gastrointestinal motility. However, little information is available on the electrical and contractile activities induced by distension in the murine small intestine. Spatiotemporal electrical mapping and mechanical recordings were made from isolated intestinal segments from different regions of the murine small intestine during distension. The electrical activity was recorded with 16 extracellular electrodes while motility was assessed simultaneously by tracking the border movements with a digital camera. Distension induced propagating oscillatory contractions in isolated intestinal segments. These propagating contractions were dictated by the underlying propagating slow wave with superimposed spikes. The frequencies, velocities, and direction of the propagating oscillations strongly correlated with the frequencies (r = 0.86), velocities (r = 0.84), and direction (r = 1) of the electrical slow waves. N(omega)-nitro-L-arginine methyl ester decreased the maximal diameter of the segment and reduced the peak contraction amplitude of the propagating oscillatory contractions, whereas atropine and verapamil blocked the propagating oscillations. Tetrodotoxin had little effect on the maximal diameter and peak contraction amplitude. In conclusion, distension in the murine small intestine does not initiate peristaltic reflexes but induces a propagating oscillatory motor pattern that is determined by propagating slow waves with superimposed spikes. These spikes are cholinergic and calcium dependent.     

Pancreatic secretion is the migratory cue for Hymenolepis diminuta in rat small intestine

Pylorus and bile-duct restrictions did not prevent the anteriad migration of Hymenolepis diminuta in rat small intestine after food feeding. However, migration was inhibited when the common bile-duct was occluded. The results indicate that pancreatic secretion is the migratory cue for Hymenolepis diminuta in rats.     

Initiation of distension-induced descending peristaltic reflex in opossum esophagus: role of muscle contractility

The balloon distension (BD)-induced descending peristaltic reflex in the opossum smooth muscle esophagus is abolished in vitro when a Ca(2+)-free Krebs solution is placed at the site of distension, suggesting that either synaptic transmission occurs at the origin of the reflex or initiation of the reflex requires the development of muscle tension in response to BD. To test the latter possibility, an 8- to 10-cm length of smooth muscle esophagus was placed in a dual-chamber organ bath, isolating the stimulating (orad) from the recording site (aborad). Nifedipine addition to the orad chamber (i.e., site of distension) inhibited the BD-induced "off" contractions in both chambers in a concentration-dependent manner. However, the aborad response to electrical field stimulation (EFS) was unaffected. Atropine addition to the orad chamber had no effect on BD or EFS responses in either chamber. To examine the effects of these agents on tonic contractility, an isobaric barostat was employed. Pressure-volume curves were not altered by Ca(2+)-free Krebs solution, nifedipine, or TTX, suggesting that resting esophageal tone is not dependent on neural factors or muscle contractility. However, both Ca(2+)-free Krebs solution and nifedipine markedly decreased phasic contractions over the top of the distending bag. These observations suggest that local, stretch-induced phasic muscle contraction is required for initiation of the BD-induced descending peristaltic reflex.     

Hymenolepis diminuta: effects of decerebration on thermal response behavior.

Hymenolepis diminuta propels itself with unidirectional peristaltic-like waveforms. When intact adult H. diminuta are placed in a thermal gradient, with the anterior proglottids hot relative to the posterior proglottids, the worms migrate up the gradient toward the hot side. When the anterior is cold, relative to the posterior, the worms moved slightly or little. These behaviors in a thermal gradient represent true thermokinetic responses for an organism with undirectional locomotion. Removal of the scolex, containing the worm's cerebral ganglia, did not significantly alter these thermal responses. These data suggest that the peripheral nervous system is capable of integrating sensory input over the length of the strobila and coordinating locomotory behavior, in the absence of the central nervous system.     

The behavior of parasitic flatworms in vivo: what is the role of the brain?

The ecological interactions that contribute to successful host-parasite relationships are complex and involve all levels of biotic organization between the participants. At the level of parasites living within their hosts, it is felt that the parasite's environment is predictable because of host mechanisms maintaining biochemical and physiological homeostasis. It is hypothesized that fixed behavior patterns in the parasites will evolve under these specialized conditions. Current thinking on fixed behaviors in invertebrates holds that they are generated by specialized neural circuits in the brain. Therefore, it can be expected that the brains of parasitic flatworms will have important roles in the control of the organisms' behaviors. However, in the tapeworm Hymenolepis diminuta, complex fixed patterns of behavior, associated with locomotion and migration, are not affected by the removal of the worm's brain. This suggests peripheral, and not central, control of fixed behaviors. In Fasciola hepatica, at least 6 distinct fixed patterns of behavior are responsible for guiding the worm to its final habitat in the liver. Giant neurons and other phylogenetically advanced features develop in the adult worm's brain after the expression of the sequence of distinct migration behaviors. Yet, there is no apparent new locomotory behavior, corresponding to the new advanced brain, as the parasite assumes its placid life-style as a hematophage in the bile duct. Removal of the adult brain of this parasite also does not appear to affect worm locomotory activity. Thus, the regulation and control of locomotion may not be the only important roles for the brains of parasitic flatworms. It is suggested that neuroethological approaches may hold the key to understanding the biology of these parasites.     

Histology of adult Litomosoides carinii (Nematoda: Filarioidea)

The histology of male and female Litomosoides carinii was studied in serial sections. The body wall of the female worm consists of a rather thin cuticle, very extended lateral hypodermal chords and small sectors of shallow coelomyarian muscle cells. In the female worm an intestinal lumen is found, which is filled with material throughout the worm's length. Both ovaries are situated close to the posterior end. In both genital tubes all stages of oogenesis and embryogenesis could be observed in approximately equal stages of development in most of the sections. The lateral chords of the male worm are very small, whereas the somatic muscle cells are large and of the circomyarian type. The intestine is a minute tube beside the much thicker testis and vas deferens. Considerable sexual dimorphism could be observed in almost all organs of adult Litomosoides carinii.     

Biochemical effects of thiabendazole and cambendazole on Hymenolepis diminuta (Cestoda) in vivo

An investigation of the chemotherapeutic and biochemical effects of two benzimidazole anthelmintics, thiabendazole (TBZ) and cambendazole (CBZ), on Hymenolepis diminuta in experimentally infected rats is reported. Thiabendazole was active against H. diminuta at a relatively high dosage. A single oral dose of TBZ at 250 mg/kg body weight on day 15 of infection eliminated 100% of the tapeworms as determined at necropsy 5 days after treatment. The chemotherapeutic actions of TBZ on H. diminuta were accompanied by marked changes in worm weight and chemical composition. Tapeworms recovered from rats that had received a therapeutically effective dose of TBZ 24 hr earlier were significantly smaller and contained much less glycogen (as a percent of the wet weight) than worms from unmedicated controls. Protein concentrations increased in TBZ-treated worms and at a rate sufficient to offset the decline in glycogen concentration. Glycogen/protein ratios in TBZ-treated worms were significantly lower than the corresponding control values. Cambendazole proved to be five times more potent than TBZ against H. diminuta and produced the same basic changes in worm weight and chemical composition within 18 hr of treatment of the host. Administration of a single oral dose of TBZ or CBZ to the host produced in H. diminuta another change, the onset of which coincided with, or preceded, the gross alterations in worm weight and chemical composition. That change, observed in in vitro studies carried out 14 hr after treatment, revealed that tapeworms from drug-treated rats absorbed and metabolized much smaller quantities of exogenous glucose than did the controls, and the ability of the worm to accumulate glucose against a concentration difference was significantly depressed.     

Study of the effects of insulin on the migration of Hymenolepis diminuta in rats

The effects of insulin on worm (Hymenolepis diminuta) migration was studied. Insulin injection (20 U/kg, s.c.) significantly increased gastric acid output but did not affect the serotonin content of blood, intestinal lumen or worms. The drug produced, dose-dependently, posteriad migration of the worms in rats without pylorus-ligation but ligation of the pylorus prevented this migration. It is concluded that the hypersecretion of gastric acid induced by insulin is responsible for the posteriad migration of H. diminuta in rats.     

High definition mapping of circular and longitudinal motility in the terminal ileum of the brushtail possum <Emphasis Type="Italic">Trichosurus vulpecula</Emphasis> with watery and viscous perfusates

Longitudinal and radial movements during spontaneous contractions of isolated segments of terminal ileum of the brushtail possum, a species of arboreal folivore, were studied using high definition spatiotemporal maps. Segments obtained from specimens were continuously perfused with solutions of various apparent viscosities at 3 cm and 5 cm hydrostatic pressure. A series of sustained tetrodotoxin-sensitive peristaltic events occurred during perfusion. The leading edge of each peristaltic event progressed by a succession of rhythmic surges of circular contraction with concerted concurrent phasic longitudinal contractions. Three types of peristaltic event were observed, with differing durations of occlusion and patterns of cyclic, in phase, circular and longitudinal contractions. Each peristaltic event was preceded by a change of shade on the D map that indicated circumferential dilatation. Differences in the slopes of these phasic shade changes from those occurring during peristalsis indicate that this distension is passive and likely results from aboral displacement of fluid. Tetradotoxin insensitive longitudinal contraction waves of frequency 9.2 min⁻¹ occurred during and in the absence of peristalsis, originating at a variety of sites, and propagating either in an orad or aborad direction but predominantly in the latter. Perfusion with 1% guar gum, at 5 cm hydrostatic pressure caused the lumen to become distended and the generation of peristaltic events to cease pending reduction of the hydrostatic head to 3 cm but longitudinal contractile activity was preserved. Neither the frequencies nor the rates of progression of circular and longitudinal contractile events, nor the temporal coordination between these events, varied with the apparent viscosity of the perfusate or altered in a manner that could facilitate mixing.     

The effect of age on the rhythmic contractions of the rat small intestine

In vivo and in vitro rates of intestinal rhythmic contractions were measured in the same rats varying in age from very young to the senescent. Two rat strains, three small intestine locations, and six ages were compared. Contraction rates determined in vivo and in vitro were similar. Rhythmic contractions at all ages were fasted in the duodenum, slower in the jejunum, and slowest in the ileum. Contractions at 10 days of age were significantly slower than at all other ages; otherwise no systematic age-associated difference in contractions was demonstrated in either strain. Several factors were suggested as possibly influencing the developmental aspects of contraction rate and, therefore, their potential involvement in the early post natal period was suggested. It appears that old age does not influence the rate at which rhythmic contractions occur in the small intestine of the rat, and very possibly, these results are applicable to other species including humans.     

Differential establishment and survival of Hymenolepis diminuta in syngeneic and outbred rat strains.

Experimental Hymenolepis diminuta infection was carried out in inbred strains of rats (F344/N, JAR-2, LOU/M, TM, DA and DA-bg/bg) and outbred Wistar rats. All strains became infected with this cestode, but clear strain-dependent variation in the susceptibility to H. diminuta infection was observed. Marked differences in worm persistence and worm weight were found at 6 weeks post-infection in TM and DA rats. These strains would be useful to clarify the interactions between H. diminuta and its rat host.     

Inhibition of growth of a tapeworm Hymenolepis diminuta in its normal host (rat).

The biomass of 8-day-old worms of Hymenolepis diminuta in secondary infections, administered to rats 3-10 days after chemotherapeutically expelling a primary infection, was 70-90% less, and the worms were more posteriorly distributed, than in naive controls. The strong depressive effect on growth waned rapidly over 2-5 weeks, but even in rats not challenged until 17 months later, worm growth was weakly depressed by 30%. The extent to which growth was depressed in a secondary infection was independent of the number of worms in the challenge but increased with number of worms in the immunizing infection up to four to eight worms. Further increase up to 64 worms had little effect. This suggests, as it is known that the biomass of worms in a rat reaches a maximum with infections of between five and 10 worms, that the change in the intestine is proportional to biomass, not number, of worms. It is argued that partially suppressed immuno-inflammatory changes in the intestine, which will affect secondary worms so strongly, will also have depressed growth and fecundity effects on the primary worms, that a dynamic equilibrium is reached between the strength of the intestinal response and the biomass of the tapeworm, and that it is reaching this equilibrium, not a 'crowding effect', which limits H. diminuta to a level compatible with the survival of the rat.     

Gastrin-releasing peptide is a modulatory neurotransmitter of the descending phase of the peristaltic reflex

The physiological role of gastrin-releasing peptide (GRP) and of its cognate receptors in regulating the intestinal peristaltic reflex was examined in a three-compartment flat-sheet preparation of rat colon. Mucosal stimulation applied to the central compartment at high, but not low levels of intensity, induced GRP release in the caudad compartment where descending relaxation was measured, but not into the ascending compartment where ascending contraction was measured or into the central compartment where the stimuli were applied. The selective GRP (BB(2)) receptor antagonist, [D-Phe(6),des-Met(14)]bombesin(6-14), inhibited descending relaxation and VIP release in the caudad compartment induced by high but not by low levels of stimulation applied to the mucosa in the central compartment. The selective neuromedin B (BB(1)) receptor antagonist, BIM-23127, had no effect on descending relaxation or VIP release. Neither the BB(1) nor the BB(2) antagonist had any effect on ascending contraction or substance P release in the orad compartment. Consistent with the effects of the antagonists on the peristaltic reflex, the BB(2) antagonist but not the BB(1) antagonist decreased the velocity of propulsion of artificial fecal pellets through isolated segments of guinea pig distal colon. The results indicate that GRP is selectively released from myenteric neurons in descending pathways during the peristaltic reflex and that it acts via BB(2) receptors to augment the descending phase of the peristaltic reflex and propulsion.