Cuminaldehyde induces oxidative stress-mediated physical damage and death of Haemonchus contortus

Cuminaldehyde (CA), a monoterpenoid, preset in many plant sources including cumin, induces reactive oxygen-related damage and death in Haemonchus contortus, a parasitic worm with an LD50, values of 127.3 ± 7.5, 184.5 ± 12.1 and 104.1 ± 7.9 μg/mL for an adult female, adult male worms (12 h) and L3 larvae, respectively (24 h). Fifty percent of inhibition of egg hatching (IC50) was obtained at 142.4 ± 11.4 μg/mL after 48 h of exposure. Scanning electron microscopy revealed physical damage to the anterior and posterior ends, intestinal, ovarian, and esophageal regions of the warms on exposure to ca. The exposure of worms to CA also led to a systemic increase in reactive oxygen species (ROS) within 3 h. The better activity was seen with CA compared to standard antihelminthic drug albendazole (Alb). 74 μg/mL CA showed 2.3 fold more increase of catalase (CAT), 0.61 fold increase of superoxide dismutase (SOD), 3.3 fold increase of glutathione peroxidase (GPx) activity and 17.5 fold increase of glutathione (GSH) activity in comparison with Alb (500 μg/mL) for the same time of exposure (3 h). A firm increase of (2.9 fold) was also observed in nitric oxide synthase (NOS) activity within 12 h of exposure with CA (74 μg/mL) in comparison with Alb. Therefore the preclinical potential of CA is much higher than widely used antihelminthic drug Alb. The results open new opportunities to explore CA as a new active antihelminthic molecule.

Amphidial structure of ivermectin-resistant and susceptible laboratory and field strains of Haemonchus contortus

The development of anthelmintic resistance by nematode parasites is a growing problem for veterinarians, pet owners, and producers. The intensive use of the macrocyclic lactones for the treatment of a variety of parasitic diseases has hastened the development of resistance to this family of parasiticides. As a result, resistance to ivermectin, moxidectin, nemadectin, and doramectin by Haemonchus contortus has been documented throughout the world. Sensory neurons located in the cephalic end of nematodes are in close contact with the external environment. Through these neurons, important chemical and thermal cues are gathered by the parasite. Examination of serial electron micrographs of ivermectin-susceptible and ivermectin-resistant H. contortus allows for comparison of neuronal structure, arrangement of neurons within the amphidial channel, and distance of the tip of the dendritic processes to the amphidial pore. The latter of these characteristics provides a useful means by which to compare the association between the neurons and the external environment of the worm. Comparison of parental laboratory strains of ivermectin-susceptible strains of H. contortus with related selected, ivermectin-resistant strains and with a wild-type ivermectin-susceptible field strain of H. contortus from Louisiana reveal that the ivermectin-resistant worms examined have markedly shorter sensory cilia than their ivermectin-susceptible parental counterparts. Additionally, the amphidial neurons of ivermectin-resistant worms are characterized by generalized degeneration and loss of detail, whereas other neurons outside of the channels, such as the labial and cephalic neurons, are normal in structure. These findings raise a number of questions regarding the relationship between amphidial structure and ivermectin resistance as well as the role of amphids as a means of entry for ivermectin. While shortened amphidial sensilla are associated with ivermectin resistance, it remains unclear if such a structural modification facilitates survival of nematodes exposed to macrocyclic lactones.

Redescriptions of Haemonchus mitchelli and Haemonchus okapiae (Nematoda: Trichostrongyloidea) and description of a unique synlophe for the haemonchinae

In the course of a revision of Haemonchus Cobb, 1898 (Nematoda), commonly referred to as large stomach worms, significant new morphological information was discovered that allows the recognition of 2 species believed for more than 50 yr to be synonymous. Both species, Haemonchus mitchelli Le Roux, 1929, from the eland Taurotragus oryx and other African ruminants and H. okapiae van den Berghe, 1937, from the okapi Okapia johnstoni, have a synlophe of 42 ridges, but the synlophe of H. mitchelli is longer than that of H. okapiae. The distal tip of the left spicule of H. mitchelli bears a barb that is about twice as long as the short barb and half as long as the long barb on the right spicule. In contrast, the barb on the left spicule of H. okapiae is similar in size to the short barb and about 25% as long as the long barb of the right spicule. The dorsal ray of H. mitchelli is bifurcated distally for 25-39% (32%) of its length and its stem is expanded proximally, but the dorsal ray of H. okapiae is bifurcated 37-50% (42%) and its stem is of uniform thickness.

Distinct characteristics of two intestinal protein compartments discriminated by using fenbendazole and a benzimidazole resistant isolate of Haemonchus contortus

The intestine of Haemonchus contortus is hypersensitive to the effects of the anthelmintic fenbendazole (FBZ). The effects are postulated to stem from disruption of microtubules and interference with apical secretory vesicle transport, followed by release of digestive enzymes into the intestinal cell cytoplasm. Here, FBZ caused marker proteins for both apical (pepsinogen-like protease, PEP-1) and basal (cystatin-like protein) protein compartments to became homogeneously distributed in the cytoplasm of H. contortus intestinal cells. The observations with PEP-1 support the hypothesis that release of hydrolytic enzymes into the intestinal cell cytoplasm contributes to the mechanism of benzimidazole efficacy. A benzimidazole resistant isolate of H. contortus expressed type 1 and 2 intestinal beta-tubulin transcripts that would encode predominantly tyr200 and phe200 variants, respectively. This isolate was resistant to the known intestinal cell alterations induced by FBZ treatment in the susceptible isolate, including inhibition of apical vesicle transport. These results implicate type 1 beta-tubulin in mediating apical vesicle transport in intestinal cells and suggest that the tyr200 variant is a determinant of FBZ resistance in intestinal cells. In contrast, the basal protein compartment demonstrated sensitivity to FBZ treatment in these otherwise "resistant" worms. Hence, distinct FBZ-sensitive components appear to be involved in distributing intestinal proteins into the described apical and basal compartments of normal worms.

Localization of p-glycoprotein mRNA in the tissues of Haemonchus contortus adult worms and its relative abundance in drug-selected and susceptible strains

Membrane transporter P-glycoproteins (Pgps) are present in a number of nematode species, including Haemonchus contortus. Allelic variation in some Pgp genes has been found to be associated with resistance to the anthelmintic ivermectin (IVM), although functional verification of a role for Pgps in IVM resistance has yet to be demonstrated. By in situ hybridization, the distribution of Pgp mRNA was visualized in transverse cryosections of adult H. contortus, using a digoxigenin-labeled cDNA probe encoding the ATP-binding region of an H. contortus Pgp. The probe sequence targeted a conserved ATP-binding region of Pgp-A (97.9% identity). It also shared 49.7-71.1% identity with 11 other Pgp sequences previously identified in H. contortus and may hybridize these sequences to give an overall measure of the total P-glycoprotein mRNA. Staining was predominately localized along the intestinal tract of the worms, with the most intense staining localized in the pharynx and anterior intestine. In the mid- and posterior intestinal regions, staining was restricted to the luminal side of the intestine. Some staining was also associated with the vas deferens and the lateral hypodermal chords anterior to the nerve ring. Using densitometry, the levels of Pgp mRNA in the pharynges of unselected and IVM- and moxidectin (MOX)-selected strains of male and female H. contortus were compared. No differences were detected between the levels of expression of Pgp in the susceptible strain versus the IVM- or MOX-selected strains. Evidence in the literature suggests that not all Pgp homologues are linked to chemical resistance phenotypes. It is thus possible that expression of I of the H. contortus Pgps is altered in IVM-resistant strains but that this phenomenon was undetectable in our experiments.

Sensory neuroanatomy of a passively ingested nematode parasite, Haemonchus contortus: amphidial neurons of the third-stage larva

The sensory neuronal ultrastructure of the amphids of the infective larva (L3) of Haemonchus contortus was analyzed, compared, and contrasted with that of the first-stage larva (L1). As in L1, each amphid of the L3 is innervated by 12 neurons. Thirteen ciliated dendritic processes of 10 neurons, 3 with double processes, lie in each amphidial channel. The dendritic process of each finger cell neuron ends in a large number of digitiform projections or "fingers," many more than in the L1. Processes of another pair of specialized neurons, probable homologs of wing cells in Caenorhabditis elegans, extend into the extreme anterior tip of the larva; they are much longer than those in L1. In L3, the neurons exit through the posterior wall of the amphidial chamber individually rather than in a bundle, as in L1. Cell constancy between L1 and L3 was confirmed, and the neurons were individually identified. Significant neuron-specific variations, presumably related to functional differences between the 2 stages were observed. In contrast, species-specific differences are surprisingly small. Haemonchus contortus is closely related to hookworms and has amphidial structure nearly identical to that in hookworms and similar to that in C. elegans, to which it is also closely related.

Thermotaxis and thermosensory neurons in infective larvae of Haemonchus contortus, a passively ingested nematode parasite

As a basis for studies of thermal behavior of infective larvae (L3) of Haemonchus contortus resulting from ablation of amphidial neurons, the locations of the amphidial cell bodies in the hatchling larva (L1) were compared with their locations in the L3. We sought to verify that killing each targeted cell body in L1 destroys the putative corresponding dendrite of the L3. These comparisons confirmed the predicted cell body-to-dendrite connections, as well as similarities in the general amphidial structure of the two stages. We then conducted a series of studies using laser microbeam ablation of amphidial cell bodies in the L1 to determine the role of specific neurons in the thermal behavior of the L3. In a thermal gradient, normal L3 of H. contortus migrate to the temperature at which they were cultured and/or maintained. Larvae grown at 16 degrees or 26 degrees C migrate appropriately to either of these temperatures. Larvae grown to the L3 stage at 16 degrees C and then moved to 26 degrees C become acclimated to this temperature and thereafter migrate to it. However, when the putative thermosensory neurons, the finger cell neurons (AFD), were ablated in hatchling larvae with a laser microbeam, and these were grown to the L3 stage and tested on a radial thermal gradient, they failed to migrate to their culture temperature. Instead, they moved actively and continuously over much of the assay plate surface, with no obviously oriented cryo- or thermotactic movement. Ablation-control larvae, those in which putatively chemosensory neuron classes ASE or AWC were killed, migrated normally to their culture temperature. When the RIA interneurons (identified by positional homology with those of Caenorhabditis elegans) were ablated, the operated larvae moved actively, but circled near the initial placement point; control larvae, in which other nonamphidial neurons were killed, migrated normally. These results indicate that the finger cell neurons (AFD) are the primary thermosensory class in H. contortus. The RIA-class neurons integrate thermal responses in H. contortus, as do their putative structural homologs in C. elegans, but the behavior of H. contortus subsequent to RIA ablation is strikingly different.

Sensory neuroanatomy of a passively ingested nematode parasite, Haemonchus contortus: amphidial neurons of the first stage larva

When infective larvae of Haemonchus contortus (a highly pathogenic, economically important, gastric parasite of ruminants) are ingested by grazing hosts, they are exposed to environmental changes in the rumen, which stimulate resumption of development. Presumably, resumption is controlled by sensory neurons in sensilla known as amphids. Neuronal function can be determined by ablation of specifically recognized neurons in hatchling larvae (L1) in which neuronal cell bodies are easily visualized using differential interference microscopy. Using three-dimensional reconstructions from electron micrographs of serial transverse sections, amphidial structure of the L1 is described. Each amphid of H. contortus is innervated by 12 neurons. The ciliated dendritic processes of 10 neurons lie in the amphidial channel. Three of these end in double processes, resulting in 13 sensory cilia in the channel. One process, that of the so-called finger cell, ends in a number of digitiform projections. Another specialized dendrite enters the amphidial channel, but leaves it to end within the sheath cell, a hollow, flask-shaped cell that forms the base of the amphidial channel. Although not flattened, this process is otherwise similar to the wing cells in Caenorhabditis elegans; we consider it AWC of this group. Two other neurons, ASA and ADB, appear to be homologs of wing cells AWA and AWB in C. elegans, although they end as ciliated processes in the amphidial channel, rather than as flattened endings seen in C. elegans. Each of the 12 amphidial neurons was traced to its cell body in the lateral ganglion, posterior to the worm's nerve ring. The positions of these bodies were similar to their counterparts in C. elegans; they were named accordingly. A map for identifying the amphidial cell bodies in the living L1 was prepared, so that laser microbeam ablation studies can be conducted. These will determine which neurons are involved in the infective process, as well as others important in establishing the host-parasite relationship.

Eosinophil-mediated killing of Haemonchus contortus larvae: effect of eosinophil activation and role of antibody, complement and interleukin-5

Eosinophils have previously been shown to accumulate around the tissue invasive (L3) stage of sheep gastrointestinal parasites in vivo. In this study, eosinophils obtained from mammary washes of sheep, were shown to immobilize and kill H. contortus larvae in vitro in the presence of antibody specific against a defined L3 surface antigen. Eosinophils obtained from sheep primed by repeated infusion of H. contortus larvae were more effective than eosinophils obtained after a single infusion of parasite extract in Fasciola hepatica infected ewes suggesting the former were activated in vivo. The level of larval immobilization in the presence of antibody was significantly increased when complement was added to cultures containing activated eosinophils. The addition of interleukin-5 to larval cultures containing antibody and complement resulted in a significant increase in larval immobilization with unactivated eosinophils suggesting that eosinophil effector function is enhanced following priming with this cytokine. Ultrastructural analysis of the eosinophil/larvae interaction at 6 h of incubation revealed degranulation of adhering eosinophils onto the surface of larvae. By 24 h of incubation, many larvae showed signs of damage and most eosinophils had degenerated. These results suggest that eosinophil-mediated killing may be an effector mechanism for the elimination of L3 H. contortus larvae in immune sheep.

Digital image analysis and identification of eggs from bovine parasitic nematodes

Computer-assisted microscopy and multivariate statistics were used to establish and evaluate a procedure for identification of bovine strongylid eggs. Ostertagia ostertagi, Cooperia oncophora, Haemonchus placei, Trichostrongylus axei, and Oesophagostomum radiatum eggs were obtained from faeces voided by monospecifically infected calves. Images of single eggs (400 x magnification) were recorded by a CCD camera fitted onto a microscope and digitized on a PC. After separation of eggs from the image background, the pixel (picture element) positions of the egg outline were analysed by algorithms to describe size and shape. A stepwise discriminant analysis was subsequently used to select and rank descriptive features of 4207 eggs according to discriminatory power. Classification criteria were developed by linear discrimination analysis on the basis of selected features, and the criteria evaluated by cross-validation. A maximum average percentage of correct classification of 85.8% resulted when nineteen features were employed in a linear classification criterion. The percentages correct classification for each species were: O. ostertagi 76.3%, C. oncophora 90.8%, O. radiatum 87.8%, H. placei 90.1%, and T. axei 83.8%. Classification based on the five most important features gave an overall correct classification of 81.5%. Images of "unknown' eggs could be identified automatically by the classification criteria after procedural steps performed by PC were linked in a batch program.

Use of free living stages to study the effects of thiabendazole, levamisole, pyrantel and ivermectin on the fine structure of Haemonchus contortus and Heligmosomoides polygyrus

Ultrastructural changes induced in vitro by thiabendazole, levamisole, pyrantel and ivermectin in the free living larval stages of two trichostrongyles (Heligmosomoides polygyrus and Haemonchus contortus) were analysed. The observed damage for each anthelmintic is related to the known mode of action and compared to the damage commonly described in adults. The advantage of using larvae to study the effects of anthelmintics on the fine structure of nematodes rather than adults is described. Thiabendazole induced alteration of the cellular organization especially epithelial cells of the digestive tract. Changes in mitochondria were also seen. Levamisole caused contraction of muscle fibres whereas no specific lesions were observed with pyrantel. Ivermectin caused an hypertrophy of muscular groups. The interest of such a technique in research on the modes of action of anthelmintics is emphasized.

The effects of closantel treatment on the ultrastructure of Haemonchus contortus

H. contortus were recovered from sheep 0-14 h after intramuscular treatment with closantel. Ultrastructural examination revealed that mitochondria were more electron dense and contained swollen cristae compared with untreated controls. Following treatment, the basal channels in the intestine became prominent and there was vesicle formation in all organs examined. In contrast, closantel-resistant H. contortus appeared normal after drug treatment. It is likely that closantel affects membrane associated processes responsible for fluid and ion homeostasis as well as mitochondrial function. Untreated H. contortus were maintained in balanced salt solution for 12 h which caused lesions indicative of fluid imbalance, but at 23 h there were serious structural abnormalities.

Bilateral, perivulval cuticular pores in trichostrongylid nematodes

A new hypodermal gland was discovered in female nematodes of the family Trichostrongylidae. Because the new structure appears to be associated with the vulva, it was named the perivulval pore. It is similar, based on light and scanning electron microscopy, to phasmids that are located laterally on the tails of nematodes of the class Secernentea. Like phasmids, perivulval pores are paired and bilateral, with cuticular ducts to the surface in the areas of the lateral chords. They are located slightly posterior to the vulva in Haemonchus contortus, Haemonchus placei, Haemonchus similis, Mecistocirrus digitatus, Mazamastrongylus pursglovei, Ostertagia ostertagi, and Cooperia oncophora, but in Trichostrongylus colubriformis they are slightly anterior to the vulva. Because of the location near the vulva and the similarity in structure to phasmids, which are, at least in part, secretory, the perivulval pores should be considered as a possible source of a female attractant for males.

Sublateral hypodermal chords in Haemonchus (Nematoda: Trichostrongyloidea): description and potential as a systematic character

Prominent sublateral hypodermal chords (SHC) are described in Haemonchus spp. Four large SHC are located 1 muscle cell away from the lateral chords from the level of the middle of the esophagus to midbody. The SHC are largest in midbody and merge with the lateral chords at about 65% of the body length from the anterior end. With the aid of transmission electron microscopy, a band of nerve tissue was located parallel and medial to the SHC. Haemonchus spp. and Mecistocirrus digitatus have SHC that are so large they can be identified in thick freehand midbody cross sections cut with a cataract knife. Because SHC have not been described in other Trichostrongylidae, their presence in members of the Haemonchinae may have value as a systematic character.

Characterization of the eggshell of Haemonchus contortus--I. Structural components

1. By transmission electron microscopy, the eggshell of Haemonchus contortus was seen to be similar to previously studied nematodes, with an outer vitelline layer bounded by a trilaminate membrane, a broad medial region, containing chitin, and an electron dense basal region, containing lipid and protein. 2. Exposure of Haemonchus contortus eggs to proteases resulted in disruption of the shell with removal of components of the outer, medial and basal regions. Exposure to chitinase depleted fibrillar components of the medial region of the shell, while collagenase had no effect. 3. Chloroform/methanol extraction of fresh eggshells caused a minor condensation of the outer, vitelline layer and some depletion of the basal layer. 4. After normal hatching, shells appeared similar to those treated with protease and chitinase, but also lacked the basal, lipid layer. 5. Extracts of isolated unhatched eggshells and hatched eggshells, and extracts of biotin-labelled whole fresh eggs showed three major protein bands when run on sodium dodecyl sulphate-polyacrylamide gels indicating that these three proteins are most likely structural in nature and do not participate in the release of the larva from the eggshell. 6. Biotin-labelled protein bands were degraded by proteases and chitinase, but not collagenase or lipase.

Interaction between the nematode-destroying fungus Arthrobotrys robusta (Hyphomycetales) and Haemonchus contortus infective larvae in vitro

In an in vitro trial, the effect of the nematode-destroying fungus Arthrobotrys robusta on Haemonchus contortus infective larvae was evaluated in petri dishes containing corn meal agar. After seven days incubation at 25 degrees C, 92.33% (+/- 4.1) predation was recorded.

Ultrastructural changes associated with exsheathment of infective juveniles of Haemonchus contortus

Ultrastructural changes associated with exsheathment of the infective juveniles of Haemonchus contortus are described. Hyaline ring formation occurs associated with annulations 10 and 20 and consists of the dissolution of the basal zone and the inner electron-dense layer resulting in the rupture of the sheath. These changes are consistent with the action of a protease-exsheathing enzyme. There is a significant reduction associated with exsheathment in the size of the excretory cells and the number of excretory granules contained within them. No changes in the oesophagus were observed associated with exsheathment. These, and the observations of earlier workers, suggest that it is the excretory cells and not the oesophagus which are the source of exsheathing fluid during exsheathment.

Biochemical and immunochemical characterization of 125I-labeled cuticle components of Haemonchus contortus

Live Haemonchus contortus developmental stages were radioiodinated and then subjected to a stepwise extraction procedure consisting of a buffer extract (with or without detergent) to solubilize putative surface-associated antigenic macromolecules, followed by a detergent/beta-mercaptoethanol (BME) extract to solubilize putative cuticle collagen proteins. A buffer-extracted iodinated 100-kDa protein was present in the free-living, infective L3(2M) stage. This labeled protein was released during in vitro exsheathment of L3(2M) and was not present in the ecdysed second molt (2M) cuticle. In addition to the 100-kDa protein, exsheathment fluid contained a 70-kDa labeled protein that was not extracted from iodinated L3(2M) with either detergent or BME. The data suggest that these proteins are components of the specialized ring portion of the 2M cuticle that is enzymatically ruptured during ecdysis. The L3(2M) and the exsheathed third-stage larvae (L3) contained 3 labeled, BME-extracted, collagenase-sensitive proteins of 108, 88 and 53 kDa. In contrast, four detergent-extracted, collagenase-insensitive, iodinated proteins (143, 81, 58 and 30 kDa) were present in adult H. contortus. The 143-kDa protein was both glycosylated and immunogenic. All 4 adult cuticle proteins were released from the cuticle surface into culture fluids. Furthermore, a cysteine protease was secreted by adults which apparently hydrolyzed the released 81-, 58- and 30-kDa surface proteins.

Scanning electron microscopy of the sheathed infective larva and parasitic third-stage larva of Haemonchus contortus (Nematoda: Trichostrongyloidea)

Scanning electron microscopy was used to describe the infective and parasitic third-stage larvae of Haemonchus contortus, the large stomach worm of ruminants. Infective larvae are ensheathed in the cuticle of the second stage, so the descriptions are of the second- and third-stage cuticles. Both larval stages had an inner circle of 6 labial papillae, an outer circle of 6 labial papillae and 4 somatic papillae, and lateral amphidial pits. Infective larvae (cuticle of the second stage) had the 6 internal labial papillae on prominent bluntly rectangular lappets in a star-shaped arrangement around a large triradiate mouth, small triangular or round amphidial pits, flattened ribbonlike lateral alae, and phasmidial apertures opening on the ventral surface of the lateral alae. Parasitic third-stage larvae had the 6 internal labial papillae on small elevations without lappets around a small mouth; large, oval amphidial pits; ribbonlike lateral alae for most of their length, but with the anterior 30-40 microns of the alae cordlike; and phasmidial apertures on the body cuticle ventral to the lateral alae.

Light and scanning electron microscopy of the ecdysis of Haemonchus contortus infective larvae

During the second ecdysis of ruminant trichostrongyles, a region of the second molt cuticle is digested by a 44-kDa Zn-metalloprotease. We have examined this digestion process by light and scanning electron microscopy (SEM). The substrate region of the cuticle appeared, during the ecdysis process, as an indented ring at the 20th cuticular annulus coincident with the anterior terminus of the lateral alae. Continued digestion of the cuticle resulted in holes in the ring region that expanded until they became continuous and separation occurred between the anterior and posterior portions of the cuticle. Mechanical movements of the L3 forced aside the cuticle cap that generally remained attached on one side to the posterior portion as the larva escaped from the sheath. The site of secretion of the 44-kDa ecdysing enzyme causing cuticle digestion was not clear from morphological observations; however, existing evidence strongly points to the release of enzyme from the esophageal (pharyngeal) glands through the mouth.

Endotube-brush border complexes dissected from the intestines of Haemonchus contortus and Ancylostoma caninum

A procedure for the blunt dissection of the syncytial intestine of Haemonchus contortus to separate the endotube-brush border complex is described. A similar complex can be obtained from the partially cellular intestine of Ancylostoma caninum. The structural features of the complexes from the two sources are compared. The main differences are in the retention of terminal bars by the endotube from A. caninum and in the extent and organization of the microfilaments associated with the basal side of the endotubes.

A helical, polymeric extracellular protein associated with the luminal surface of Haemonchus contortus intestinal cells

The structure of the intestinal cells of the parasitic nematode Haemonchus contortus is described. The cells have numerous microvilli about 0-09 micron in diameter; most being 5-5-7-5 micron in length. The microvillar (plasma) membrane is coated with a layer of amorphous material (glycocalyx) about 60 A thick which is electron dense in sectioned preparations. Associated with the surface of this material, and filing the spaces between the microvilli, are filaments in the form of helices about 400 A in diameter and of variable pitch. The helices appear to be flexible but they are aligned approximately with the long axes of the microvilli. There are up to ten helices per microvillus; they extend beyond the tips of the microvilli and are up to 10 micron long. The material has been obtained nearly pure in small amounts. It is primarily protein and it is proposed that it should be called contortin. The monomeric form (of molecular weight about 60,000) has been identified with a Y-shaped structure with arms about 45 A long and 25 A wide seen in negatively stained preparations. The helical filament appears to be formed by lateral polymerization of patirs of these units.

A method of collecting and processing nematode larvae for electron microscopy

A method is described using simple apparatus for separating and concentrating nematode larvae from host faecal material and a recommended procedure is given for processing the helminths for transmission electron microscopical examination.