Characterization of polysaccharides of the eggs and adults of Hymenolepis diminuta.

Polysaccharides and other complex carbohydrates were released by proteolysis of the chloroform-methanol insoluble residue of 10 day-old worms and eggs of Hymenolepis diminuta. Gas-liquid chromatographic analysis of alditol acetate derivatives of monosaccharides released from the polysaccharides by hydrolysis revealed that in the 10 day-old worm, glucose was the most abundant sugar, followed by galactose, glucosamine, galactosamine, fucose and possibly rhamnose. Mannose was least abundant and xylose was absent. In the egg, glucose and galactose were equally abundant, followed by the same sugars found in 10 day-old worms, and xylose was present. Uronic acid was detected in both fractions by specific chemical tests. None of the saccharide material from eggs and worms was susceptible to degradation by Streptomyces hyaluronidase, chondroitinase AC, and slightly susceptible to chondroitinase ABC, as shown by electrophoretic analysis on composite 2.2% acrylamide-agarose slab gels and 4.5/12.5% polyacrylamide gels before and after enzymatic treatment. One of the gel-separable bands, however, was degradable by both nitrous acid and Flavobacterium heparinase. Both bands from eggs were degradable by nitrous acid. These results suggest that eggs contain heparin and/or heparan sulfate and perhaps dermatan sulfate and that 10 day-old worms also have these polyglycans but possibly not chondroitin sulfate or hyaluronic acid.

Toxocara canis infection of the eye. Correlation of clinical observations with developing pathology in the primate model.

A primate model for the study of Toxocara canis infection was created by intravitreal, periocular, systemic, and intracarotid injection of viable larvae in cynomolgus monkeys. The results were as follows: (1) Intravitreal larvae caused retinal hemorrhages, perivasculitis, mild vitritis, and retinal nodules. (2) Apparently viable larvae without inflammatory reaction were found in the vitreous, retina, and optic nerves up to nine months after intravitreal inoculation. (3) Other larvae were surrounded by an acute inflammatory granuloma or a chronic fibrotic granuloma, but they did not appear to be necrotic. (4) Toxocara canis larvae apparently had the ability to move through ocular tissue, to leave the site of tissue reaction, and to exit via the optic nerve. Viable larvae were found in the retina up to 15 months after inoculation. (5) Culture fluid containing Toxocara proteins stimulated a severe retinal vasculitis. Dead larvae caused little reaction. (6) Positive aqueous and vitreous enzyme-linked immunosorbent assay titers were found in the most severely inflamed eyes, which often harbored live larvae.

Effect of inoculum size and length of infection on the distribution of Toxocara canis larvae in the mouse.

The effect of inoculum size and time on the distribution of Toxocara canis larvae in the mouse was investigated by recovering larvae from various body regions 7, 14, 28, and 56 days after administration of either 200, 600 or 1,000 infective eggs to groups of ten male mice. An analysis of variance of larval recoveries from the carcass, liver, brain and cardiopulmonary system suggests that inoculum size was a significant factor determining the proportional recovery for each of these sites. Length of infection was significant in relation to numbers of larvae in the anterior carcass, genitourinary system, brain and heart plus lungs, while length of infection and inoculum size acting in concert influenced the numbers of larvae recovered from the carcass, liver, brain, heart and lungs. Crowding effects, manifested as altered dispersion rates, were seen in the heavier infections.

Small intestinal transections decrease the occurrence of tapeworm-induced myoelectric patterns in the rat.

Abstract Luminal infection by the noninvasive tapeworm, H. diminuta, alters rat small intestinal myoelectric activity. The significance of continuity between small intestinal enteric nervous system (ENS) and that of both the stomach/pylorus and colon/caecum regarding the induction of tapeworm-altered myoelectric patterns was evaluated. A total of 32 rats were implanted with four serosal electrodes placed at sites in the duodenum through the mid-jejunum. Sixteen of the 32 rats underwent intestinal transections and anastomoses at both the duodenum and ileum. After recording myoelectrical activity of both normal and transected intestines, eight rats from each group (normal and transected) were infected with H.diminuta. Phase III frequency, duration of the migrating myoelectric complex (MMC), slow wave frequency, percentage of slow waves associated with spike potentials and the occurrence of the the two tapeworm-initiated myoelectric patterns, repetitive bursts of action potentials (RBAP) and sustained spike potentials (SSP), were measured. In infected rats, the frequency of the RBAP and SSP electric patterns were significantly reduced by the double transection. Intestinal transection did not affect the other changes caused by infection, such as decreased MMC phase III frequency and percentage of slow waves associated with spike potentials. In conclusion, a small intestinal ENS in continuity with other segments of the GI tract is required to generate maximal numbers of tapeworm-induced SSP and RBAP myoelectric activity in the small intestine of the rat.

Ultrastructure of lineus ruber (Rhyncocoela) epidermis.

Recent evidence indicates that nemertean epidermis is capable of absorbing certain organic solutes from sea water via mediated transport mechanisms, as well as secreting mucoid substances. Morphological studies suggest that these functions may be restricted to distinct epidermal cell populations. Mucous secretion at the free surface of the epidermis is the result of synthesis and release activites of cells in both the epidermis and dermis (cutis). Secretion of dermal origin passes through the epidermis to the worm's exterior in slender cytoplasmic process (process (canaux d'evacuation) in the form of membrane bound vesicles. A single gland cell type, located entirely within the epidermis, releases externally a granular product histochemically identified as largely protein plus some amount of carbohydrate with low periodic acid-Schiff's reactivity. The close juxtaposition of granular endoplasmic reticulum and Golgi apparati to the secretory material is consistent with the composition of this secretory product. Interstitial cells possess microvilli projecting from their apical surface, in addition to cilia. The outer surface of the plasmalemma covering these ciliary projectons is unadorned, but microvilli possess a fuzzy coat. At the peripheral ends of the microvilli, the coat is filamentous, while at their base the coat consist of foliate structures. Cationic colloidal iron binding suggest that the filamentous portion of the fuzzy coat contains the greatest proportion of the acidic surface charge. The presence of periodic acid-Schiff's positive material in this region suggests that the fuzzy coat also contains carbohydrate. Lateral boundaries of the interstitial cell lacks obvious junctional specializations; however, the apical 150 nm intracellular space narrows to 40 nm and continues in a tortuous interdigitating path to the base of the adjacent interstitial cells. Where the apex of these cells is broad, the interdigitations are shallow, but the basal half of the interstitial cells have deep complex infoldings. Cytoplasmic organelles other than the nucleus, mitochondria and some granular endoplasmic reticulum, are restricted to the apical half of the cytoplasm. The presence of closely apposed Golgi complexes and smooth endoplasmic reticulum, multivesicular bodies, lysosome-like dense vesicles and coated vesicles suggests that these cells may play a role in intracellular digestion of phagocytized particulate matter from the external environment. The amplification of the interstitial cell's free surface suggests that these cells are primarily responsible for mediated solute transport across the epidermis.

Mechanical integration of muscle, tegument, and subtegumental tissues by anchoring fibrils and microfibrils in the cestode Hymenolepis diminuta.

Electron microscopic examination of the epidermal basement membrane region of the rat tapeworm, Hymenolepis diminuta, has revealed specialized connective tissue structures that appear to anchor the epidermis, or tegument, to the parenchymal tissues of the helminth, as well as interconnect subtegumental muscle fibers, tegument, and parenchyma. Anchoring fibrils-cross-banded bundles of ca. 3 nm diameter filaments--were observed to directly interlink tegument and muscle, muscle and muscle, and tegument, muscle, and parenchymal connective tissue. Anchoring fibrils therefore appear to mechanically integrate epidermal tissue movements in response to subtegumental muscle contraction. A well-developed stratum of microfibrils, forming the lamina reticularis of the tegumental basement membrane, may also help anchor the tegument as well as to serve as a flexible, reinforcing sheath that protects parenchymal tissues from excessive radial displacement due to muscle contraction.

Location of carbohydrate in the tegument of the procercoid of Spirometra mansonoides.

Carbohydrate distribution within vesicles of the tegumental cytoplasm of the procercoid of Spirometra mansonoides indicated that there are at least three morphologically and histochemically different vesicular types, but only one vesicular type was present in the subtegumental perikarya. This distribution of vesicles and the presence of morphologically intermediate forms could represent either the discontinuous, sequential synthesis of the various vesicular types or continued differentiation of vesicles observed in the synthetic regions of the perikarya once they move to the tegumental cytoplasm.

Ileal mucosal mast cell, eosinophil, and goblet cell populations during Hymenolepis diminuta infection of the rat.

The population dynamics in the enteric connective tissues of eosinophils, mucosal mast cells (MMC), and in the mucosal epithelium of goblet cells were examined morphometrically in fixed ileal tissue of outbred Sprague Dawley rats during the first 32 days of infection with the tapeworm Hymenolepis diminuta. MMC and eosinophils were present in the lamina propria and submucosa; however, only eosinophils were also present in the muscularis externa. Eosinophilic infiltrate was first observed in the lamina propria at 15 days postinfection (dpi) and the numbers of eosinophils remained elevated through 32 dpi. Initial mucosal mastocytosis was detected on 6 dpi and MMC numbers continued to rise over the study period without reaching a plateau. Goblet cell hyperplasia occurred only at 32 dpi. In contrast to some intestinal nematode infections where these same 3 cell types are associated with the host's expulsion responses, H. diminuta is not lost by a rapid host response in the outbred Sprague Dawley rat strain used in these experiments. We suggest that either the induction of hyperplasia of these host effector cells in ileum tissue during H. diminuta infection is not capable of triggering parasite rejection mechanisms, or the function of the induced hyperplasia is necessary for some as yet unassociated physiological or tissue architecture change in the host's intestine.

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.

Modulation of caudal intestinal permeability in the rat during infection by the tapeworm Hymenolepis diminuta.

Bidirectional movement of solutes between the intestinal lumen and systemic circulation is restricted by tissue barriers that may be altered under conditions such as intestinal infection. In a study using an in vitro everted sac preparation to assess small intestinal permeability in a lumen-to-serosa direction, 51Cr-EDTA movement was compared regionally in the jejunum and ileum of rats infected and uninfected by tapeworms. Whereas jejunal segments showed no significant differences in permeability to 51Cr-EDTA at 6, 15, or 32 days postinfection (dpi), ileal segments displayed an increased permeability on 15 and 32 dpi, but not 6 dpi. The alterations in permeability were not reversed 1 wk after removal of the tapeworm from the intestine. In conclusion, the strictly lumen-dwelling tapeworm infection allows increased movement of molecules from the lumen into ileal, but not jejunal, tissues by 15 dpi.

Hymenolepis diminuta fractions but not previous tapeworm infection stimulate intestinal myoelectric alterations in vivo in the rat.

Infection of rats with the enteric, lumen-dwelling tapeworm Hymenolepis diminuta causes electric changes in host intestinal smooth muscle and decreased luminal transit. The mechanisms that stimulate host intestinal alterations during this nontissue invasive infection may include the tapeworm's biomass, its diurnal migratory behavior, a host immune-mediated response, or direct parasite stimulation of host motor activity. In vivo intestinal myoelectric activity was monitored to evaluate the following: (1) that reinfection with H. diminuta is influenced by host immune regulation and (2) that administration of tapeworm fractions to never-before-infected rats initiates an alteration of enteric smooth muscle activity. To address the first hypothesis, we determined that altered intestinal myoelectric activity patterns were no different and did not occur earlier in a second infection with H. diminuta than in a primary infection. The lack of either a change in myoelectric pattern or an earlier onset of intestinal myoelectric changes indicates that tapeworm-induced myoelectric activity is not anamnestically stimulated by host immunomodulatory mechanisms. Consistent with the second hypothesis, administration of either H. diminuta carcass homogenate or tegument-enriched fractions directly into the intestinal lumen of tapeworm-naive rats initiated myoelectric patterns previously characteristic of chronic H. diminuta infection. Additionally, the appearance of characteristic nonmigrating myoelectric patterns in uninfected rats administered tapeworm fractions indicates that a substance from H. diminuta acts as the triggering signal molecule for intestinal myoelectric alterations. These findings also indicate that neither the tapeworm's biomass nor its diurnal movement is required for initiation of H. diminuta-altered myoelectric patterns. We have shown that H. diminuta possess a signal molecule(s) that alters host enteric electric activity, and we suggest that these alterations may play an important role in the symbiotic rat-tapeworm interrelationship.

Praziquantel treatment normalizes intestinal myoelectric alterations associated with Hymenolepis diminuta-infected rats.

Hymenolepis diminuta-associated alterations in rat intestinal myoelectric patterns are abolished following therapeutic administration of the anthelmintic praziquantel (PZQ). Host intestinal smooth muscle myoelectric patterns, reflecting smooth muscle contractility and intestinal phasic motility, were recorded using in vivo serosal electrodes, surgically implanted on the duodenum, jejunum, and ileum. Repeated electromyographic recording from unrestrained and unanesthetized rats began 5 days after electrode implantation surgery. Three initial control recordings from each rat confirmed the appearance of normal intestinal myoelectric patterns, characterized by the interdigestive migrating myoelectric complex (MMC). All animals were subsequently infected with H. diminuta and myoelectric recordings beginning after day 8 postinfection confirmed the appearance of diminished frequency of the MMC and 2 nonmigrating myoelectric patterns, i.e., repetitive bursts of action potentials and sustained spike potentials. PZQ was used to remove the tapeworms from rats 12 days after Hymenolepis diminuta infection, as intestinal myoelectric changes become maximal at this time in tapeworm-infected rats. PZQ administered to uninfected rats at either of 2 dose levels did not affect host interdigestive myoelectric activity. After removal of the parasite with PZQ, electromyographic recordings indicated a return to normal uninfected electrical patterns within 24 hr of drug treatment. We have demonstrated that the presence of Hymenolepis diminuta is necessary to induce and maintain abnormal intestinal myoelectric patterns. The altered motor properties of tapeworm-infected rat intestine and the rapid reconversion to preinfection myoelectric patterns provides a new and unique model to examine the regulatory mechanisms of intestinal motility and its control by luminal parasites.

A simple method of obtaining an enriched fraction of tegumental brush border from Hymenolepis diminuta.

A method for isolating an enriched preparation of tegumental brush border from the tapeworm, Hymenolepis diminuta, is described. Combining incubation of whole tapeworms in Krebs-Ringer/tris-maleate solution containing a hemolytic saponin, low shear-force agitation, and differential centrifugation, a pellet is obtained at 2,500 g which contains a significant concentration of surface brush border. The content of brush border in this fraction is identified by the presence of numerous microvilli, increased specific radioactivity after surface tagging with 3H-Concanavalin A, and relatively little mitochondrial contamination (succinic dehydrogenase). Based on morphological criteria, fractions sedimenting with greater force contain dense vesicles and mitochondria from the outer portion of the tegument.

Lipids from subcellular fractions of the tegument of Hymenolepis diminuta.

Lipids comprised 37% and 22.1%, respectively, of the day weights of brush border- and vesicle-rich fractions separated by differential centrifugation of isolated H. diminuta tegument. Neutral lipids of both fractions were rich in cholesterol, but also contained small amounts of glycerides, sterol esters, and (in brush borders) free fatty acids. Phosphatidyl ethanolamine was the most prevalent polar lipid in both fractions, and was particularly abundant (63.4% of total polar lipids) in vesicles; sphingomyelin, not previously reported from H. diminuta, was also present. Polar lipids of both tegumental fractions resembled each other but differed from whole worm polar lipids in fatty acid composition. Tegumental polar lipids contained lower levels of long-chain, polyunsaturated fatty acids than reported for corresponding lipids of whole worms.

Lethal effects of freezing Echinococcus multilocularis eggs at ultralow temperatures.

Methods for killing Echinococcus multilocularis eggs within stool or intestinal samples, without damaging the diagnostic value of the sample, would significantly reduce the risk of animal health providers acquiring alveolar hydatid disease. The first objective of this study was to determine whether E. multilocularis eggs located in fox intestines can survive storage at -70 C for at least 4 days. Results showed that none of 72,000 E. multilocularis eggs remained infectious to defined strains of mice under these conditions, yet, similar eggs recovered from nonfrozen carcasses stored at 4 C for the same time period were viable. The structural identities of adult worms and eggs were not significantly altered by the freezing and thawing processes. These results indicate that ultracold temperatures can be used to kill or inactivate E. multilocularis eggs, making them safe to handle when diagnosing this parasite in definitive hosts. The second objective of this study was to determine whether E. multilocularis eggs could survive freezing to -70 C if commonly used cryopreservation protocols were used. The use of the cryoprotectant solution, 5% dimethyl sulfoxide-35% saline-60% lamb serum, with a -1 C/min freezing rate was unable to prevent the eggs from being killed by freezing to -70 C. Rapid cooling by plunge freezing into liquid nitrogen was also lethal to E. multilocularis eggs. Only a few of the many potential cryopreservation protocols were tested in this study, so it is not yet possible to completely rule out the possibility of preserving these eggs at ultralow temperatures, but it does indicate that temperatures below -70 C are lethal to eggs even under favorable storage conditions.

Effect of tunicamycin on the uptake and incorporation of galactose in Hymenolepis diminuta.

The effects of tunicamycin (TM) on the uptake and incorporation of tritiated galactose into the tegumental membrane and carcass from adult Hymenolepis diminuta were examined to assess the potential usefulness of this inhibitor for studying the function of the tapeworm surface glycocalyx. Hymenolepis diminuta adults (11 days old) were preincubated for 1 hr, pulsed for 30 min with [3H]galactose and [14C]leucine, and chased for 2 hr; replicate experiments were conducted in which all media contained no TM or TM at 10 micrograms/ml. Tunicamycin significantly inhibited the incorporation of tritiated galactose into the tapeworm's carcass and 30,000-g tegumental membrane fraction. Incorporation of tritiated galactose into the tapeworm's tegumental surface membrane also was inhibited significantly when expressed relative to the incorporation of [14C]leucine. Tunicamycin did not affect the amounts of free, i.e., soluble, [3H]galactose or [14C]leucine recovered from the tapeworms not did it affect the short-term (2 min) uptake of [3H]galactose by tapeworms. Thus, the inhibitory effect of TM appears to be at the level of protein glycosylation rather than carbohydrate (galactose) transport. The data indicate that TM might be useful for producing tapeworm surface membranes with diminished carbohydrate moieties.

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.

Disruption and removal of the tegument from Schistosoma mansoni with triton X-100.

Tegumental membranes of Schistosoma mansoni were disrupted by 0.2% Triton X-100 in Tris-maleate buffered/Kreb-Ringer's solution. Subsequent differential centrifugation of the disruption solution at 2,500 g and 30,000 g produced two pellets which contained membrane components. Examination of the carcass by scanning electron microscopy revealed that most of the exposed tegument of both male and female worms was removed, while surface membrane protected by close apposition of another surface (i.e., in the gynecophoral canal) remained intact. The parenchymal tissue (e.g., subtegumental muscle and tegumental perikarya), excretory and gut epithelia, and the tegument's basement membrane also remained intact. The selectivity of the disruption suggests that membrane in both pellets originated almost exclusively from the tegument. Although larger morphological features (i.e., surface crypts) present in the intact tegument did not maintain their form in the 2,500 g pellet, the high specific activity of 3H-concanavalin A retained by this fraction, and the presence of numerous spines and large pieces of membrane, suggest that the 2,500 g pellet contained most of the worm's disrupted surface membrane. Transmission electron microscopy demonstrated the presence of dense spinelike material and vesicles of various sizes and densities, as well as some mitochondria in the 30,000 g pellet. Low specific activity of 3H-concanavalin A in the post-30,000 g supernatant suggests that relatively few externally oriented, saccharide-containing molecules were solubilized from tegumental membranes by Triton X-100.

Comparison of calcium, freeze-thaw, and Triton X-100 tegumental disruption/recovery techniques applied to Schistosoma mansoni.

Three techniques for the disruption/recovery of tegumental free-surface plasmalemma were compared by (i) morphological examination of carcasses and centrifugally-derived isolates, (ii) specific enrichment of bound surface tags (lectin) and of "marker" enzymes for membrane, and (iii) assessment of total protein and lectin recovered by each procedure. Procedures compared included the use of Triton X-100, freezing and thawing, and high ionic strength calcium. Triton X-100 consistently provided the greatest amounts of recovered surface membrane on a per worm basis, whereas calcium retained the highest amounts of alkaline p-nitrophenyl phosphatase, adenosine triphosphatase, and adenosine monophosphatase activity. Ultrastructural examination of membrane isolates and worm carcasses prepared by freezing and thawing indicated that significant amounts of parenchymal material contaminated the membrane fractions. Thus results based on the freeze-thaw technique can be difficult to interpret.

Immunocytochemical localization of the major glutathione S-transferases in adult Schistosoma mansoni.

Indirect immunofluorescence was used to investigate the tissue distribution of the major isoenzymes of Schistosoma mansoni glutathione S-transferase (GSH S-transferase). When polyclonal rabbit antisera against GSH S-transferase isoenzymes SmGST-1, -02, and -3 were applied to cryostat or plastic-embedded sections of fixed adult worms, a punctate pattern of enzyme distribution was observed that was restricted to the parenchyma. Labeling was much more pronounced in males than females, consistent with the biochemically determined distribution of these enzymes between the sexes. Intense immunolabeling was noted within the subectocytoplasmic core tissue of the tubercles of the male that appeared to be connected to deep parenchymal cells by immunoreactive cell processes. Immunofluorescence could be blocked completely by prior incubation of antisera with affinity-purified enzyme. Although schistosome GSH S-transferases have been reported to be protective antigens, no immunoreactivity was detected within or on the tegument, including the dorsal spines of the male. The lack of tegumental immunoreactivity was confirmed by immunoblotting of tegumental membrane preparations following SDS-PAGE. Muscle fibers, vitelline cells, and cecal epithelium also failed to react. The fact that the GSH S-transferases were not uniformly distributed among all parenchymal cells suggests the existence of subpopulations of parenchymal cells that are preferentially involved in the conjugation of electrophiles with glutathione.