The life cycle of Anguina agrostis: Embryogenesis

Bpird A. F. and Sptynes B. A. 1981. The life cycle of Anguina agrostis: embryogenesis. International Journal for Parasitology11: 23–33. Egg development, from laying to hatching, of two widely separated populations of Anguina agrostis, has been followed over a range of temperatures. Development rates for these two populations have been shown to be identical with a thermal optimum between 18 and 20°C. The minimum time recorded for embryogenesis through to hatching was 9–10 days.Embryogenesis was inhibited by temperatures of 27°C and above and hatching by temperatures greater than 23°C.No significant differences were detected in the dimensions of eggs from either population. These eggs have an average length of 95 μm and an average width of 38 μm.Electron microscope studies of sections through eggs undergoing synchronous development show that the first and apparently only moult of the larva in the egg commences about 7 days after the start of embryogenesis under optimal conditions. The sequence of morphological events that occur throughout embryogenesis are described and recorded for whole specimens observed at low resolution and the moulting sequence is described from high resolution electron micrographs of the cuticles of synchronously developing embryos and larvae.     

Biosynthesis of biopterin in Ascaris lumbricoides suum

In in vivo experiments, radioactivity from [U-¹⁴C]GTP was incorporated into biopterin, and, in fact, all carbon atoms of biopterin synthesized in Ascaris lu lumbricoides suum originated from GTP.Biopterin was also biosynthesized in homogenates of tissue fluid and muscles of Ascaris lumbricoides suum.The enzyme which catalyzes sepiapterin synthesis from D-erythto-7,8-dihydroneopterin-3′-phosphate was found in A. lumbricoides suum extracts and extracted in the 0–30% (NH₄)₂SO₄ fraction from a 40 000 × g supernatant. The enzyme was purified by Sephadex G-200 column and DEAE-cellulose column chromatography. It is suggested that sepiapterin could be an intermediate compound in biopterin biosynthesis.     

Ascaris suum and Toxocara canis: Egg extract antigens in guinea pigs and the macrophage migration inhibition test

Guinea pigs immunized with 500 μg of either Ascaris suum or Toxocara canis egg extracts, emulsified with Freund's complete adjuvant, were skin tested with both the homologous and heterologous antigens. Cross-reactions were observed in both groups. Migration of macrophages from sensitized animals was more inhibited by homologous than by heterologous antigens. Lymph-node lymphocytes from sensitized animals were stimulated to incorporate [⁸H]thymidine similarly by both antigens.     

Value of the specific distinction between Ascaris lumbricoïdes linné 1758 and Ascaris suum Goeze 1782

Ansel M. and Thibaut M. 1973. Value of the specific distinction between Ascaris lumbricoïdes Linné 1758 and Ascaris suum Goeze 1782. International Journal for Parasitology3: 317–319. Study by scanning electron microscopy of heads of Ascaris lumbricoides Linné 1758 and Ascaris suum Goeze 1782 showed typical distinctive characteristics between these two species. There are differences in the appearance of the rows of denticules and the shapes of the lips.     

Development of nested multiplex polymerase chain reaction (PCR) assay for the detection of Toxocara canis, Toxocara cati and Ascaris suum contamination in meat and organ meats

Ascarid Larva Migrans Syndrome (ascarid LMS) is a clinical syndrome in humans, caused by the migration of animal roundworm larvae such as Toxocara canis, Toxocara cati and Ascaris suum. Humans may acquire infection by ingesting embryonated eggs, or infective larvae of these parasites in contaminated meat and organ meats. To detect these pathogenic contaminations, a novel nested multiplex PCR system was developed. Our novel nested multiplex PCR assay showed specific amplification of T. canis, T. cati and Ascaris spp. Detection limit of the nested multiplex PCR was tested with serial dilution of T. canis, T. cati or A. suum genomic DNA (gDNA) from 100?pg to 100 ag and found to be 10?fg, 1?fg and 100?fg, respectively. When larvae were spiked into chicken liver tissue, DNA of T. canis and A. suum was detected from the liver spiked with a single larva, while the assay required at least 2 larvae of T. cati. Moreover, the ascarid DNA was detected from the liver of mice infected with 100 and 300 eggs of T. canis, T. cati or A. suum. This nested multiplex PCR assay could be useful for the detection of contamination with ascarid larvae in meat and organ meats.     

The life cycle of Anguina agrostis: Development in host plant

Bird A.F. and Stynes B.A. 1981. The life cycle of Anguina agrostis: Development in the host plant. Internationaljournal for Parasitology11: 431–440. The growth and development of the infective second stage “dauer” larvae (DL₂) of Anguina agrostis into adults have been followed under field conditions in rye grass (Lolium rigidum). Three moults were observed to occur during the parasitic phase of development. From the third (second parasitic) moult onwards, there was much more variability in the size of the female nematodes than in the males and sexual dimorphism became very pronounced. The transition from the DL₂ to the second stage parasitic larva (PL₂) is marked by the disappearance of the numerous lipid storage granules which are characteristic of the DL₂, and the development in the PL₂ of an intestine which becomes more pronounced in each succeeding stage, particularly in the adult female. Anguina agrostis is unusual among parasitic nematodes in that the DL₂ has the thickest cuticle of all stages, including adults. The L₄ and adult males have thicker cuticles than the females at the same stages of development. Moulting appears to involve resorption of the innermost basal zone of the shed cuticle as well as morphological and chemical changes to the epicuticle.     

The life history of Labiostrongylus eugenii, a nematode parasite of the Kangaroo Island wallaby (Macropus eugenii): development and hatching of the egg and the freeliving stages

Smales L. R. The life history of Labiostrongylus eugenii, a nematode parasite of the Kangaroo Island Wallaby (Macropus eugenii): development and hatching of the egg and the free living stages. International Journal for Parasitology7: 449–456. Labiostrongylus eugenii (Trichonematidae) occurs in the stomach of the Kangaroo Island Wallaby. Egg morphology is similar to that of other strongyloids. When incubated at 25°C embryogenesis is completed in about 30 h. An incomplete moult occurs within the egg, and larvae hatch at a sheathed second-stage $\text{43}\text{1}\text{2}\text{–83}\text{1}\text{2}$ h later. Development occurred at all temperatures between 2° and 37°C with an optimum about 25°C and an upper limit near 37°C. The hatching process is very rapid, taking about 2 min. It is signalled by increased larval activity followed by a change in shell permeability. The larva hatches at that pole of the shell which has become plastic.The sheathed second-stage larva measures 659.50 ± 22.54 μm by 27.98 ± 1.22 μm. Its internal structures are concealed by a mass of opaque granules which were demonstrated as neutral lipid by oil red O staining. A second incomplete moult at 3–4 days results in a doubly sheathed infective larva from which the lipid gradually disappears. The mouth never appears patent and the larvae neither feed nor grow but rather decrease in size with age. Optimal temperatures for larvae range between 15°–25°C with 37°C about the upper limit. The significance of this developmental pattern is discussed.     

Reversible inhibition of hatching of infective eggs of Ascaris suum (Nematoda)

Hurley L. C. and Sommerville R. I. 1982. Reversible inhibition of hatching of infective eggs of Ascaris suum (Nematoda). International Journal for Parasitology12: 463–465. Dilute solutions of an oxidising agent, iodine, reversibly inhibit hatching of infective eggs of Ascaris suum. The capacity to hatch is restored by exposure to reducing agent, hydrogen sulphide. These observations add to known similarities between hatching of infective eggs and exsheathment of infective larvae. It is proposed that the regulatory mechanisms for both processes are similar.     

Development of larvae of Ascaris suum from the third to the fourth stage in a chemically defined medium

Third stage larvae of Ascaris suum, recovered from the lungs of rabbits 7 days after oral infection with eggs, were cultured to the fourth larval stage in chemically defined, low molecular weight medium. The medium consisted of tissue culture medium 199, supplemented with glucose and glycyl-hystidyl-lysine and gassed with a mixture of N₂-CO₂-O₂ (90:5:5). Growth and development in this medium were similar to that in media supplemented with whole serum or with a serum dialysate.     

Ascaris lumbricoides: Coproporphyrinogen oxidase activity in eggs and muscle

The possible presence of coproporphyrinogen oxidase (EC 1.3.3.3), an oxygen-requiring enzyme in the porphyrin biosynthetic pathway, was investigated in supernatant fractions of homogenized Ascaris lumbricoides muscle and developing eggs, and in mitochondrial preparations of muscle. Compared with rat liver controls, low levels of enzyme activity were found in A. lumbricoides gut, 6-day eggs, and muscle mitochondria. Enzyme activity in muscle, 8-day, and 25-day eggs was not measurable under the conditions employed.     

Succinate dehydrogenase and fumarate reductase activity in Aspiculuris tetraptera and Ascaris suum and the effect of the anthelmintics cambendazole,thiabendazole, and levamisole

Comley John C. W. and Wright Spdenis J. 1981. Succinate dehydrogenase and fumarate reductase activity in Aspiculuris tetraptera and Ascaris suum and the effect of the anthelmintics cambendazole, thiabendazole, and levamisole. International Journal for Parasitology11: 79–84. Succinate dehydrogenase and fumarate reductase activities from a particulate fraction of A. tetraptera and a soluble extract of A. suum have been determined using spectrophotometric methods. Fumarate reductase activity in A. suum could only be detected anaerobically. Succinate dehydrogenase activity from A. suum was partially characterized and shown to exist in several multimolecular forms (isoenzymes). The in vitro effect of the anthelmintics cambendazole, thiabendazole and levamisole on succinate dehydrogenase and fumarate reductase activity from the above nematodes are described. Significant inhibition of fumarate reductase activity of both nematodes was only achieved using 5 mM levamisole and 1 mM thiabendazole. After in vivo anthelmintic treatment of A. tetraptera only thiabendazole significantly inhibited fumarate reductase. It is suggested that the succinate dehydro-ogenase-fumarate reductase complex in these nematodes is unlikely to be the primary site chemotherapeutic attack for any of the anthelmintics tested.     

Ascaris suum: Differential effects of Avermectin B1a on the intact animal and neuromuscular strip preparations

Avermectin B_1a, a novel antiparasitic agent, paralyzes Ascaris suum without causing either flaccid paralysis or a hypercontraction. It reduces the lengthening of the acetylcholine-preconditioned A. suum muscle strip caused by γ-aminobutyric acid. It does not affect the contraction of the isolated muscle strip preparation caused by applying acetylcholine. However, preinjection with Avermectin B_1a does significantly reduce the shortening caused by acetylcholine injection without affecting the paralysis of an intact ascarid worm. These results suggest that Avermectin B_1a may act on the central nervous system of Ascaris sp. nematodes.     

Fine binding specificities to Ascaris suum and Ascaris lumbricoides antigens of the sera from patients of probable visceral larva migrans due to Ascaris suum

Fine binding specificities to Ascaris suum and A. lumbricoides antigens of the sera from patients with probable visceral larva migrans (VLM) due to A. suum infection were examined. Although multiple-dot enzyme-linked immunosorbent assay (ELISA) was found to be useful for the primary screening of patients, identification of the responsible species was sometimes difficult due to extensive cross reactions with other ascarid parasite antigens. Fine resolution to determine the causative pathogen was obtained by a rather classical Ouchterlony's double immunodiffusion test. The difference in the binding of the patients' sera to A. suum and A. lumbricoides antigens was also demonstrated by an inhibition ELISA. The patients' antibodies bound with higher avidity to the A. suum antigen than to the A. lumbricoides and Toxocara canis antigens. Combination of at least two different immunological assay methods is recommended for the diagnosis of VLM due to ascarid parasites.     

Ascaris lumbricoides and Ascaridia galli: Biogenic amines in adults and developmental stages

Ascaris lumbricoides var. hominis and Ascaridia galli contain 5-hydroxytryptamine, histamine, dopamine, and norepinephrine. The chick parasite showed lower levels of monoamines compared to human ascaris. Amine concentrations in females were higher than in males. In all specimens, 5-hydroxytryptamine was the highest while norepinephrine was found to be uniformly low. The female reproductive organ contained the maximum amount of dopamine while intestine was rich in histamine. A progressive increase in the concentrations of biogenic amines was noticed during development.     

Ascaris suum: Oxidative phosphorylation in mitochondria from developing eggs and adult muscle

Respiration and the phosphorylating capability of mitochondria isolated from one-celled fertilized eggs, 10-day vermiform embryos, 21-day infective larvae, and adult body wall muscle from Ascaris suum were compared with that of rat liver mitochondria. Although oligomycin-sensitive ATPase and O₂ consumption/ mitochondrion in the presence of succinate and malate was lower in eggs than in liver, other properties such as respiratory control, ADP:O and P:O ratios at sites I, II, III, and the sensitivity of respiration to cyanide, azide, oligomycin, rotenone, and malonate were similar. In muscle mitochondria, the oligomycin-sensitive ATPase and O₂ consumption/ mitochondrion were sharply reduced, respiratory control was poor, and electron transport at sites II and III in particular was inefficiently coupled with phosphorylation. In addition, about 60% of the respiration was insensitive to cyanide or azide but sensitive to salicylhydroxamic acid. The results support earlier evidence that the free-living eggs of A. suum are aerobes. The adult parasite, while continuing to ferment actively in the presence of oxygen, nevertheless possesses one or more electron transport systems that are inefficiently coupled with aerobic phosphyorylations. The physiological significance of these systems has yet to be elucidated.     

Bacillus thuringiensis-derived Cry5B Has Potent Anthelmintic Activity against Ascaris suum

Ascaris suum and Ascaris lumbricoides are two closely related geo-helminth parasites that ubiquitously infect pigs and humans, respectively. Ascaris suum infection in pigs is considered a good model for A. lumbricoides infection in humans because of a similar biology and tissue migration to the intestines. Ascaris lumbricoides infections in children are associated with malnutrition, growth and cognitive stunting, immune defects, and, in extreme cases, life-threatening blockage of the digestive tract and aberrant migration into the bile duct and peritoneum. Similar effects can be seen with A. suum infections in pigs related to poor feed efficiency and performance. New strategies to control Ascaris infections are needed largely due to reduced treatment efficacies of current anthelmintics in the field, the threat of resistance development, and the general lack of new drug development for intestinal soil-transmitted helminths for humans and animals. Here we demonstrate for the first time that A. suum expresses the receptors for Bacillus thuringiensis crystal protein and novel anthelmintic Cry5B, which has been previously shown to intoxicate hookworms and which belongs to a class of proteins considered non-toxic to vertebrates. Cry5B is able to intoxicate A. suum larvae and adults and triggers the activation of the p38 mitogen-activated protein kinase pathway similar to that observed with other nematodes. Most importantly, two moderate doses of 20 mg/kg body weight (143 nM/kg) of Cry5B resulted in a near complete cure of intestinal A. suum infections in pigs. Taken together, these results demonstrate the excellent potential of Cry5B to treat Ascaris infections in pigs and in humans and for Cry5B to work effectively in the human gastrointestinal tract.     

Systematic investigation of Amphioxus (Branchiostoma floridae) microRNAs

Ascaris lumbricoides and Ascaris suum are parasitic nematodes living in the small intestine of humans and pigs, and can cause the disease ascariasis. For long, there has been controversy as to whether the two ascaridoid taxa represent the same species due to their significant resemblances in morphology. However, the complete mitochondrial (mt) genome data have been lacking for A. lumbricoides in spite of human and animal health significance and socio-economic impact globally of these parasites. In the present study, we sequenced the complete mt genomes of A. lumbricoides and A. suum (China isolate), which was 14,303 bp and 14,311 bp in size, respectively. The identity of the mt genomes was 98.1% between A. lumbricoides and A. suum (China isolate), and 98.5% between A. suum (China isolate) and A. suum (USA isolate). Both genomes are circular, and consist of 36 genes, including 12 genes for proteins, 2 genes for rRNA and 22 genes for tRNA, which are consistent with that of all other species of ascaridoid studied to date. All genes are transcribed in the same direction and have a nucleotide composition high in A and T (71.7% for A. lumbricoides and 71.8% for A. suum). The AT bias had a significant effect on both the codon usage pattern and amino acid composition of proteins. Phylogenetic analyses of A. lumbricoides and A. suum using concatenated amino acid sequences of 12 protein-coding genes, with three different computational algorithms (Bayesian analysis, maximum likelihood and maximum parsimony) all clustered in a clade with high statistical support, indicating that A. lumbricoides and A. suum was very closely related. These mt genome data and the results provide some additional genetic evidence that A. lumbricoides and A. suum may represent the same species. The mt genome data presented in this study are also useful novel markers for studying the molecular epidemiology and population genetics of Ascaris.     

Unraveling Ascaris suum experimental infection in humans

Ascaris lumbricoides and Ascaris suum are two closely related parasites that infect humans and pigs. The zoonotic potential of A. suum has been a matter of debate for decades. Here we sought to investigate the potential human infection by A. suum and its immunological alterations. We orally infected five healthy human subjects with eggs embraced by A. suum. The infection was monitored for symptoms and possible respiratory changes, by an interdisciplinary health team. Parasitological, hematological analyses, serum immunoglobulin, cytokine profiles, and gene expression were evaluated during the infection. Our results show that A. suum is able to infect and complete the cycle in humans causing A. lumbricoides similar symptoms, including, cough, headache, diarrhea, respiratory discomfort and chest x-ray alterations coinciding with larvae migration in the lungs. We also observed activation of the immune system with production of IgM and IgG and a Th2/Th17 response with downregulation of genes related to Th1 and apoptosis. PCA (Principal componts analysis) show that infection with A. suum leads to a change in the immune landscape of the human host. Our data reinforce the zoonotic capacity of A. suum and bring a new perspective on the understanding of the immune response against this parasite.     

Ascaris suum: Immunosuppression in mice during acute infection

Mice inoculated by stomach intubation with 10,000 embryonated Ascaris suum eggs, 4, 11, or 21 days before an intraperitoneal (ip) immunization with 2 × 10⁸ sheep erythrocytes (SRBC) had reduced numbers of direct (IgM) splenic hemolytic plaques measured at 4 days after immunization and only a marginal reduction in indirect plaques (IgG) measured at 9 days after immunization. Lower dosages of Ascaris eggs or simultaneous inoculation of Ascaris eggs and SRBC did not suppress antibody responses to SRBC. No reduction in a secondary antibody response to SRBC injected 4 days after Ascaris inoculation was observed. IgM and IgG hemagglutinin titers, as distinguished by 2-mercaptoethanol sensitivity, were suppressed in mice injected ip with 10⁸ SRBC 10 days following inoculation of 10,000 Ascaris eggs, but titers in both Ig classes were similar in infected and control mice injected with 2 × 10⁹ SRBC. At Day 20, antibody titers following ip injection of 1.0 or 100 μg of ovalbumin in alum were reduced in mice infected with 10,000 Ascaris eggs 4 days before antigen injection.Contact hypersensitivity to oxazalone was not altered in mice sensitized at 5 or 14 days after inoculation of 10,000 Ascaris eggs. The delayed hypersensitivity response, measured by footpad swelling, to an optimum intravenous sensitizing dosage of SRBC was inhibited in mice sensitized 10 days after Ascaris infection, but not inhibited in mice sensitized at 21 or 32 days after infection. In contrast, the delayed hypersensitivity response to subcutaneous sensitization with SRBC 10 days after Ascaris infection was not altered.     

Effect of attachment of Corynebacterium rathayi on movement of Anguina agrostis larvae

Bird A. F. and Riddle D. L. 1984. Effect of attachment of Corynebacterium rathayi on movement of Anguina agrostis larvae. International Journal for Parasitology 14: 503–511. The movement of freshly hatched larvae (FHL₂) and dauer larvae (DL₂) of Anguina agrostis was compared on ‘agarose’ plates. The DL₂S moved faster and over greater distances. They were not attracted to Corynebacterium rathayi on agar plates, but contact with this bacterium, in most instances, markedly reduced their speed of movement. This reduction was found to be approximately proportional to the concentration of the bacteria (from 8 × 10⁵ to 8 × 10⁸ per ml) to which the DL₂ were exposed prior to observation of their movement, as was the number of bacteria observed to be adhering when viewed under the light microscope. This type of bacterial attachment appeared to be largely stage specific as it was much more pronounced and characteristically different in the DL₂ from that in the FHL₂. This interaction between the DL₂ and the bacterium was similar in material from fresh and from rehydrated nematode galls so that it was apparently not dependent on any surface cuticular changes associated with anhydrobiosis. Furthermore, pretreatment of the nematodes with the surfactant SDS did not influence attachment. An electron microscope study of sections cut through DL₂ exposed to bacteria showed that this interaction was indeed not a surface phenomenon but that the bacteria exerted a pathological effect on the nematode. The bacterium's capsular material actually penetrated and broke down the nematode epicuticle and part of the cortical zone. These observations make it easier to understand the dramatic physiological responses of this nematode to these bacteria.