Culture requirements of Ascaris suum larvae using a stationary multi-well system: increased survival, development and growth with cholesterol

Long live the worms: methods for maintaining and assessing the viability of intestinal stages of Parascaris spp. in vitro

In vitro maintenance of helminth parasites enables a variety of molecular, pharmaceutical and immunological analyses. Currently, the nutritional and environmental in vitro requirements of the equine ascarid parasite, Parascaris spp., have not been determined. Additionally, an objective method for assessing viability of Parascaris spp. intestinal stages does not exist. The purpose of this study was to ascertain the in vitro requirements of intestinal stages of Parascaris spp., and to develop a viability assessment method. A total of 1045 worms were maintained in a total of 212 cultures. Worms obtained from naturally infected foals at necropsy were immediately placed in culture flasks containing 200 mL of culture media. A variety of media types, nutrient supplementation and environmental conditions were examined. A motility-based scoring system was used to assess worm viability. Worms maintained in Roswell Park Memorial Institute-1640 had significantly better viability than any other media (P < 0.0001) and all media types supplemented with any of the nutrients examined (P < 0.0001). The use of a platform rocker also significantly improved viability (P = 0.0305). This is the first study to examine the requirements for maintaining Parascaris spp. intestinal stages in vitro and to evaluate their viability based on movement using an objective scoring system.

Intestinal Enterobacteriaceae that Protect Nematodes from the Effects of Benzimidazoles

The objective of this study was to investigate an interaction between nematodes and gut Enterobacteriaceae that use benzimidazoles as a carbon source. By addressing this objective, we identified an anthelmintic resistance-like mechanism for gastrointestinal nematodes. We isolated 30 gut bacteria (family Enterobacteriaceae) that subsist on and putatively catabolize benzimidazole-class anthelmintics. C. elegans was protected from the effects of benzimidazoles when co-incubated with these Enterobacteriaceae that also protect adult ascarids from the effects of albendazole. This bacterial phenotype represents a novel mechanism by which gastrointestinal nematodes are potentially spared from the effects of benzimidazoles, without any apparent fitness cost to the parasite.

Helminths in the lungs

Parasitic helminths infect well over one billion people and typically cause chronic and recurrent infections that exert a considerable toll on human health and productivity. A significant number of important intestinal- and tissue-dwelling helminth parasites have evolved a scripted migration through select organ systems. Of specific interest here are the helminth parasites that interact with respiratory tissues and the pulmonary immune system. This review will consider the nature of the interactions between helminth parasites and the lung environment, as well as the consequences of these interactions on the evolution of parasitism and host immunity.

Role of cholesterol in parasitic infections

The requirement of cholesterol for internalization of eukaryotic pathogens like protozoa (Leishmaniasis, Malaria and Toxoplasmosis) and the exchange of cholesterol along with other metabolites during reproduction in Schistosomes (helminths) under variable circumstances are poorly understood. In patients infected with some other helminthes, alterations in the lipid profile have been observed. Also, the mechanisms involved in lipid changes especially in membrane proteins related to parasite infections remain uncertain. Present review of literature shows that parasites induce significant changes in lipid parameters, as has been shown in the in vitro study where substitution of serum by lipid/cholesterol in medium and in experimental models (in vivo). Thus changes in lipid profile occur in patients having active infections with most of the parasites. Membrane proteins are probably involved in such reactions. All parasites may be metabolising cholesterol, but the exact relationship with pathogenic mechanism is not clear. So far, studies suggest that there may be some factors or enzymes, which allow the parasite to breakup and consume lipid/cholesterol. Further studies are needed for better understanding of the mechanisms involved in vivo. The present review analysis the various studies till date and the role of cholesterol in pathogenesis of different parasitic infections.

Experimental Ascaris suum infection in the pig: protective memory response after three immunizations and effect of intestinal adult worm population

The protective immune response to larval migration in pigs, with or without adult intestinal worm populations, 10 weeks after 3 weekly Ascaris suum inoculations, was studied in 45 pigs. Controlled adult worm populations were achieved by oral transfer of 10 adult worms to previously immunized pigs after anthelmintic drenching. A significant reduction in larval recovery from lungs on day 7, and small intestine on day 14, was observed in immunized pigs compared with previously uninfected control pigs after challenge inoculation. The strong anamnestic response to larval migration was characterized by blood eosinophilia and specific immune responses measured by peripheral blood enzyme-linked immunospot and immunosorbent assays using larval excretory-secretory products and adult body fluid as well as Western blotting with a panel of stage-specific A. suum antigens. Immune detection of a previously unreported 10 kDa band, specific to the L2 larval stage and egg hatch fluid, emerged in all pigs after challenge, while the major adult body fluid constituent, ABA-1, remained unrecognized. No significant effect of an intestinal adult worm burden on the larval recovery after a challenge inoculation or on the immune response before or after challenge inoculation could be detected. These results indicate that a significant protective memory immune response to A. suum challenge inoculation can be induced in pigs, and that this protective immunity is not significantly modulated by the presence of adult parasites in the gut.

Viability of eggs, filariform larvae and adults of Strongyloides venezuelensis (Nematoda: Strongyloidea) maintained in vitro

The present study was performed to check the viability of eggs, filariform larvae and adults of Strongyloides venezuelensis exposed to various conditions for an in vitro maintenance. The eggs in the feces remained viable for about 25 days at 4 degrees C and 15 days at room temperature. However, the isolated eggs in sterile saline lost their viability within 24 hr at 4 degrees C. The eggs in morula stage were very sensitive to air drying and rapidly lost their viability (< or = 12 hr). Filariform larvae survived for a maximum period of 45 days in fecal suspension and 28 days in 0.12% nutrient broth in polyvinyl culture bags maintained at 20 degrees C. On the other hand, those isolated from nutrient broth cultures survived for a maximum period of 32 days in tap water and 22 days in sterile saline at 20 degrees C. The mature adult worms obtained from experimentally infected rats survived maximally for 9 days in serum supplemented (10% rat-serum) 0.12% nutrient broth and 4 days in serum free nutrient broth at 37 degrees C while the culture media were changed at an alternate day. The adult female worms deposited fertile eggs in serum supplemented and serum free nutrient broth cultures, however, the hatched larvae (L1) were not able to develop to the filariform stage in the culture media and found to die within 24 hr of maintenance. The present findings on an in vitro maintenance of different stages of S. venezuelensis may provide useful information for biological and biochemical studies with Strongyloides species.

Effects of plumbagin on development of the parasitic nematodes Haemonchus contortus and Ascaris suum

1. Plumbagin (5-hydroxy,2-methyl-1,4-napthoquinone) inhibited the motility and survival of Haemonchus contortus first-stage larvae (L1) with an ED50 of 1 microgram/ml, but was less effective in preventing the development of H. contortus to infective third-stage larvae in a faecal slurry assay. 2. Of the structural analogs tested, plumbagin was the most potent in preventing development of L1 followed in decreasing order of potency by 1,4-naphthoquinone, 5-hydroxy-1,4-napthoquinone (juglone) and 1,2-napthoquinone. 3. Plumbagin had a biphasic effect on development of the fourth-stage Ascaris suum larvae that caused an increase in growth at low concentrations but was lethal at higher doses. 4. Plumbagin and 1,2-napthoquinone partially inhibited embryonation of A. suum eggs.

Effect of gas phase on carbohydrate metabolism in Ascaris suum larvae

The in vitro metabolism of [1-13C]glucose by Ascaris suum third and fourth-stage larvae was analyzed under different gas phases using 13C nuclear magnetic resonance spectroscopy (13C-NMR). Third-stage larvae (L3) incubated under a gas phase of 85% N2/5% O2/10% CO2 produced trace amounts of [13C]succinate, and molted to fourth-stage larvae (L4) between days 3 and 4 in vitro. However, they appeared to arrest as L3s when incubated under air, or 85% N2/5% O2/10% CO2 in the presence of 2 mM potassium cyanide, or 95% N2/5% CO2. Day 12 L4 (eight days after molting) incubated under 85% N2/5% O2/10% CO2, or 95% N2/5% CO2, or 94% N2/1% O2/5% CO2, produced succinate, acetate, propionate and the branched-chain fatty acids 2-methylvalerate and 2-methylbutyrate by fermentative pathways characteristic of adult body wall muscle. In contrast, when Day 12 L4 were incubated under air, only trace amounts of these acids were detected in the incubation medium. Thus, L4 are capable of synthesizing end-products typical of the adult even in the presence of oxygen, as long as the CO2 tensions are above 5%. As would be predicted, activities of enzymes involved in aerobic metabolism, including citrate synthase, isocitrate dehydrogenase, and cytochrome oxidase, decreased dramatically as L4s underwent the final ecdysis and matured to the adult stage. More importantly, activities of enzymes typical of anaerobic metabolism, including phosphoenolpyruvate carboxykinase and malic enzyme, were substantially elevated in L3s (over their levels in second-stage larvae), and appeared to have reached their adult levels in L3s prior to the third molt, even though L3s still exhibited cyanide sensitivity. Since L3s and L4s have enzymes involved in both aerobic and anaerobic pathways, it is possible that the L3s contain two populations of mitochondria, one which functions aerobically and a second which functions anaerobically.

Immunochemical characterization of the pyruvate dehydrogenase complex in adult Ascaris suum and its developing larvae

Polyclonal antibody was prepared against the pyruvate dehydrogenase complex purified from adult Ascaris suum body wall muscle. The antibody reacted with the E2, X, alpha E1 and beta E1 subunits of the complex in immunoblots of mitochondrial supernatant fractions and homogenates of adult muscle. In addition, the same subunits were observed in immunoblots of homogenates of L3 and L4 ascarid larvae, suggesting that a similar enzyme complex was present in all developmental stages despite their marked differences in energy metabolism. The phosphorylated and dephosphorylated alpha E1 peptides migrated differently during sodium dodecylsulfate polyacrylamide gel electrophoresis and both forms of the enzyme were recognized by the antibody. These results and those obtained with ELISA suggest that both phosphorylated and dephosphorylated forms of the alpha E1 subunit react equally well with the antibody. In immunoblots of adult body wall muscle, the phosphorylated alpha E1 peptide predominated, while immunoblots of L3 larvae contained predominantly the dephosphorylated form. These results reflect the in vivo activity state of the pyruvate dehydrogenase complex in these two stages and suggest that this technique may be useful for determining the activity state of enzyme complex directly from immunoblots of homogenates A. suum and other helminths.

Biochemical changes during the aerobic-anaerobic transition in Ascaris suum larvae

Ascaris suum L3 larvae isolated from rabbit lungs undergo the third ecdysis to L4 larvae after 3 days in culture under a gas phase of 85% N2/10% CO2/5% O2. The L3 larvae contain substantial malic enzyme activity and are capable of producing small amounts of the reduced organic acids characteristic of the fermentative pathways which operate in the adult. However, only a small portion of the total carbon utilized is accounted for by these reduced acids and their motility is cyanide-sensitive, suggesting that their energy-generating pathways are predominantly aerobic. In contrast, after ecdysis, the L4 larvae begin to utilize glucose at a greater rate and the proportion of total carbon utilized which is accounted for as propionate, 2-methylbutyrate and 2-methylvalerate also increases. In addition, motility becomes increasingly cyanide-insensitive, suggesting that these L4 larvae are able to utilize the anaerobic energy-generating pathways of the adult. Surprisingly, on day 10 in culture, these L4 larvae, although capable of producing reduced volatile acids, still retain substantial cyanide-sensitive cytochrome oxidase activity.

Ascaris suum: role of ecdysteroids in molting

Three studies were conducted to examine the function of ecdysteroids in the development of parasitic nematodes. Ecdysone and 20-hydroxyecdysone were extracted, separated chromatographically, and measured in the reproductive tracts of adult female Ascaris suum. Perienteric fluid and the body wall did not contain measurable levels of these steroids. Levels of 20-hydroxyecdysone were correlated with the third and fourth molts of larvae grown in vitro from the third stage. In a bioassay, addition of ecdysteroid extracted from the female reproductive tract or synthetic ecdysteroid increased the proportion of third-stage larvae that molted after 4 days in culture. This evidence supports the role of ecdysteroids in molting in A. suum, as well as suggesting a function in gametogenesis and embryogenesis.

Ascaris suum: protective immunity in pigs immunized with products from eggs and larvae

Parasite products were collected at three distinct phases of development of Ascaris suum, and their immunogenicity was determined after injection into rabbits and pigs. Products were derived from (1) the hatching fluid of infective eggs; (2) the conditioned medium of 2nd-stage larvae that developed to 3rd stage in vitro in defined medium; and (3) the conditioned medium of 3rd-stage larvae that developed to 4th stage in vitro in defined medium. Protein profiles from these three preparations, separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, were less complex than that of extracts from homogenized A. suum larvae. Hyperimmune rabbit antiserum raised against either egg products, 2nd- to 3rd-stage larval excretory-secretory products, or 3rd- to 4th-stage larval excretory-secretory products showed strong homologous reactions after immunoelectrophoresis, but relatively weak cross-reactions with the other preparations. A combined enteral immunization of pigs with egg products and parenteral immunization with the 2nd- to 3rd-stage larval excretory-secretory products, and 3rd- to 4th-stage larval excretory-secretory products induced antibody to each preparation and significant protective immunity to a challenge exposure with 10,000 A. suum eggs. However, a marked pathological response to larvae migrating in the liver after challenge exposure was also induced.

Steroidal enhancement of growth in parasitic larvae of Ascaris suum: validation of a bioassay

Third-stage larvae of the swine parasitic roundworm, Ascaris suum, were grown in stationary multiwell cultures in the presence of synthetic steroid hormones or the HPLC fractions of a steroid extract of adult female reproductive tracts to determine the subsequent effect of these compounds on length of 4th-stage larvae. Log doses of ecdysone, 20-hydroxyecdysone, progesterone, and makisterone standards, from 50 pg/ml to 500 ng/ml, were incubated with larvae for 1 day in RPMI-1640 supplemented with cholesterol. Length measurements were made on 4th-stage larvae after an additional 6 days of incubation. All compounds and extracts had a dose-dependent enhancement on length of these larvae; the partially purified extracts were more potent than their synthetic analogs. All standards and extracts except makisterone showed reduced or no response at higher dose levels. In contrast, makisterone continued to have maximal effect from 500 pg/ml to 500 ng/ml. Short exposure period to the steroid and low concentration were critical to demonstrate enhanced growth in this homologous bioassay.