Effect of dewatering and composting on helminth eggs removal from lagooning sludge under semi-arid climate.

In this work, we assessed the drying and composting effectiveness of helminth eggs removal from sewage sludge of a lagoon wastewater treatment plant located in Chichaoua city. The composting was run after mixing sludge with green waste in different proportions: M1 (½ sludge + ½ green waste), M2 ([Formula: see text] sludge + [Formula: see text] green waste), and M3 ([Formula: see text] sludge + [Formula: see text] green waste) for 105 days. The analysis of the dewatered sewage sludge showed a load of 8-24 helminth eggs/g of fresh matter identified as Ascaris spp. eggs (5-19 eggs/g) followed by Toxocara spp. (0.2 to 2.4 eggs/g); Hookworm spp. and Capillaria spp. (0.4-1 egg/g); Trichuris spp., Taenia spp., and Shistosoma spp. (< 1 egg/g) in the untreated sludge. After 105 days of treatment by composting, we noted a total reduction of helminth eggs in the order of 97.5, 97.83, and 98.37% for mixtures M1, M2, and M3, respectively. The Ascaris spp. eggs were reduced by 98% for M1 and M3 treatments and by 97% for M2 Treatment. Toxocara spp., Hookworm spp., Trichuris spp., Capillaria spp., and Shistosoma spp. eggs were totally eliminated (100% decrease) and the Taenia spp. was absent from the first stage of composting. These results confirm the effectiveness of both dehydrating and composting processes on the removal of helminth eggs.

Mammalian metallopeptidase inhibition at the defense barrier of Ascaris parasite.

Roundworms of the genus Ascaris are common parasites of the human gastrointestinal tract. A battery of selective inhibitors protects them from host enzymes and the immune system. Here, a metallocarboxypeptidase (MCP) inhibitor, ACI, was identified in protein extracts from Ascaris by intensity-fading MALDI-TOF mass spectrometry. The 67-residue amino acid sequence of ACI showed no significant homology with any known protein. Heterologous overexpression and purification of ACI rendered a functional molecule with nanomolar equilibrium dissociation constants against MCPs, which denoted a preference for digestive and mast cell A/B-type MCPs. Western blotting and immunohistochemistry located ACI in the body wall, intestine, female reproductive tract, and fertilized eggs of Ascaris, in accordance with its target specificity. The crystal structure of the complex of ACI with human carboxypeptidase A1, one of its potential targets in vivo, revealed a protein with a fold consisting of two tandem homologous domains, each containing a beta-ribbon and two disulfide bonds. These domains are connected by an alpha-helical segment and a fifth disulfide bond. Binding and inhibition are exerted by the C-terminal tail, which enters the funnel-like active-site cavity of the enzyme and approaches the catalytic zinc ion. The findings reported provide a basis for the biological function of ACI, which may be essential for parasitic survival during infection.

Mutagenicity of Ascaris chymotrypsin inhibitor in germ cells of mice.

Chymotrypsin inhibitor isolated from Ascaris suum (ACHI) was tested for the induction of dominant lethal mutations in male mice. Dominant lethal effects of ACHI for the main stages of germ cell development were analyzed by mating at specific time points after dosing. Two groups of adult BALB/c males received 24 or 40 mg per kilogram body weight (BW) per day intraperitoneal (IP) injection of ACHI in sterile phosphate-buffered saline (PBS) for five consecutive days (subacute exposure). Males from a third group were administered single IP injections of ACHI-60 mg/kg BW (acute exposure). The control group received concurrent injections of PBS for five successive days. After the last dose, each male was mated with two untreated females. For fractionated examination with regard to successive germ cell stages (spermatozoa, spermatids, spermatocytes, spermatogonia), every second week, two other untreated virgin females were placed with each male for mating. The uteri of the females were inspected on the 15th day of gestation, and preimplantation loss and postimplantation loss determined from dominant lethal parameters. Exposure of mice germ cells to ACHI did not impair mating activity of males. Fertility index was reduced (P < 0.05) only for females mated at the third week with males exposed to the highest dose of ACHI. In the females bred to ACHI-treated males, significant (P < 0.05) increase in preimplantation loss was observed at postinjection weeks 1 (reflecting exposure to spermatozoa after single treatment and to spermatozoa or late spermatids after subacute dosing) and 3 (reflecting exposure to mid and early spermatids for acute dosing and to mid and early spermatids or late spermatocytes following acute treatment), regardless of dose and length of exposure to the inhibitor. At the 60-mg/kg-BW group, a significant increase of this parameter was also noted at week 5 (reflecting exposure to early spermatocytes). During mating days 15-21, a significant (P < 0.05) increase in postimplantation loss and dominant lethal effects were observed for all doses of ACHI. Acute ACHI exposure 5 weeks prior to mating resulted in dominant lethal effects in early spermatocytes. These preliminary data suggest that ACHI induces dominant lethal mutations at postmeiotic and meiotic stages of spermatogenesis, but spermatids are the most sensitive cell stage to the effect of ACHI. These results show that ACHI may be one of the factors causing disturbances in spermatogenesis leading to a reduction of host reproductive success.

Expression and bioactivity of allatostatin-like neuropeptides in helminths.

Allatostatins are the largest family of known arthropod neuropeptides. To date more than 150 different arthropod type-A allatostatins have been identified and are characterized by the C-terminal signature, (Y/F)XFG(L/I)amide. Using specific allatostatin antisera, positive immunoreactivity has been identified within the central and peripheral nervous systems of the flatworm (platyhelminth) Procerodes littoralis and the roundworm (nematode) Panagrellus redivivus. Comparative analyses of the allatostatin-like immunoreactivity and that of other known helminth neuropeptides (FMRFamide-like peptides [FLPs]) indicate differences in the distribution of these peptide families. Specific differences in neuropeptide distribution have been noted within the pharyngeal innervation of flatworms and in the cephalic papillary neurons of nematodes. In arthropods, type-A allatostatins have functions that include potent myoactivity. In this study, seven members of the allatostatin superfamily induced concentration-dependent contractions of flatworm muscle fibres. Pharmacological studies indicate that these peptides do not interact with muscle-based FLP receptors. The type-A allatostatins, therefore, represent the second family of neuropeptides that induce muscle contraction in flatworms. Although the majority of arthropod type-A allatostatins examined did not affect the somatic body wall muscle or the ovijector of the pig nematode, Ascaris suum, two type-A allatostatins (GDGRLYAFGLamide and DRLYSFGLamide) exhibited significant inhibitory effects on the A. suum ovijector at 10 microM. These data suggest that allatostatin-like peptides and receptors occur in helminths. Further, although arthropod type-A allatostatins display inter-phyla activities, their receptors are less compelling as potential targets for broad-spectrum parasiticides (endectocides) than FLP receptors.

NMR solution structure of Apis mellifera chymotrypsin/cathepsin G inhibitor-1 (AMCI-1): structural similarity with Ascaris protease inhibitors.

The three-dimensional structure of the 56 residue polypeptide Apis mellifera chymotrypsin/cathepsin G inhibitor 1 (AMCI-1) isolated from honey bee hemolymph was calculated based on 730 experimental NMR restraints. It consists of two approximately perpendicular beta-sheets, several turns, and a long exposed loop that includes the protease binding site. The lack of extensive secondary structure features or hydrophobic core is compensated by the presence of five disulfide bridges that stabilize both the protein scaffold and the binding loop segment. A detailed analysis of the protease binding loop conformation reveals that it is similar to those found in other canonical serine protease inhibitors. The AMCI-1 structure exhibits a common fold with a novel family of inhibitors from the intestinal parasitic worm Ascaris suum. The pH-induced conformational changes in the binding loop region observed in the Ascaris inhibitor ATI are absent in AMCI-1. Similar binding site sequences and structures strongly suggest that the lack of the conformational change can be attributed to a Glu-->Gln substitution at the P1' position in AMCI-1, compared to ATI. Analysis of amide proton temperature coefficients shows very good correlation with the presence of hydrogen bond donors in the calculated AMCI-1 structure.

Structural analysis of ASCUT-1, a protein component of the cuticle of the parasitic nematode Ascaris lumbricoides.

CUT-1 from the intestinal parasitic nematode Ascaris lumbricoides is a protein component of the insoluble residue of the cuticle, cuticlin. It contains the CUT-1-like domain which is shared by members of a novel family of components of extracellular matrices. The structure and the thermal stability of recombinant CUT-1 from A. lumbricoides (ASCUT-1) were investigated by Fourier-transform infrared (FT-IR) and CD spectroscopy. The data revealed that the secondary structure of the protein at 20 degrees C, both as insoluble inclusion bodies or in soluble form, contains about 50% beta structure, 14% alpha-helix and 25% turns. A tendency of A. lumbricoides CUT-1 to form aggregates was documented by FT-IR spectroscopy which showed also that the addition of SDS disrupts these interactions. Near-ultraviolet CD spectra confirmed these data and suggested that phenylalanine residues are probably involved in intermolecular hydrophobic interactions responsible for the tendency of the protein to aggregate. Near-ultraviolet spectra showed also that part of the cysteine residues forms disulphide bridges responsible for the tertiary architecture of the protein. Finally, FT-IR and CD data revealed that ASCUT-1 is very stable at high temperatures. This stability and the tendency of ASCUT-1 to form aggregates suggest that these properties may be important for a protein which is a component of a particularly resistant extracellular matrix such as the nematode cuticle.

Effects of a selective phosphodiesterase IV inhibitor (CDP-840) in a leukotriene-dependent non-human primate model of allergic asthma.

The activity of CDP-840, a novel, selective phosphodiesterase IV inhibitor was determined in a leukotriene-dependent non-human primate model of allergic asthma. Measurements of specific airway resistance (sRaw) were recorded in a dual chamber plethysmograph for 1 h and 3-5 h after challenge of allergic conscious squirrel monkeys with an aerosol of ascaris antigen. Orally administered CDP-840 (10 mg/kg; 1 h before challenge) produced partial inhibition (41 and 45%, respectively) of both the acute (1 h post antigen) response and the late (3-5 h post antigen) response to antigen but failed to alter the response to an aerosol of leukotriene D4. In a second series of experiments, intravenous CDP-840 (5 mg/kg; 30 min before challenge) showed improved potency, producing 82% inhibition of the early and 51% inhibition of the late phase response. CDP-840 was inactive when tested intravenously at 1 mg/kg and was inactive against the 3-5 h response when administered after the early phase response (5 mg/kg; i.v. 60 min post antigen challenge). The novel phosphodiesterase IV inhibitor CDP-840 selectively inhibited antigen-induced bronchoconstriction in conscious squirrel monkeys. This effect appears to be independent of any direct bronchodilator action. It is concluded that the activity of CDP-840 in this model may be due to an inhibitory effect on mediator (e.g., leukotriene) release.

Structural analysis of neutral glycosphingolipids from Ascaris suum adults (Nematoda:Ascaridida).

The neutral glycosphingolipid fraction from adults of the pig parasitic nematode, Ascaris suum, was resolved into four components on thin-layer chromatography. The high-performance liquid chromatography-isolated components were structurally analysed by: methylation analysis; exoglycosidase cleavage; gas-liquid chromatography/mass spectrometry; liquid secondary-ion mass spectrometry; and, in particular, matrix-assisted laser desorption/ionization time-of-flight mass spectrometry. Their chemical structures were determined as: Glc(beta 1-1)ceramide, Man(beta 1-4)Glc(beta 1-1)ceramide, GlcNAc(beta 1-3)Man(beta 1-4)Glc(beta 1-1)ceramide and Gal(alpha 1-3)GalNAc(beta 1-4)GlcNAc(beta 1-3)Man(beta 1-4)Glc(beta 1-1)ceramide; and were characterized as belonging to the arthro-series of protostomial glycosphingolipids. No glycosphingolipid component corresponding to ceramide tetrasaccharide was detected during these analyses. The ceramide composition of the parent glycosphingolipids was dominated by the 2-(R)-hydroxy C24:0 fatty acid, cerebronic acid, and C17 sphingoid-bases: 15-methylhexadecasphing-4-enine and 15-methylhexadecaphinganine in approximately equal proportions. The component ceramide monohexoside was characterized by an additional 15-methylhexadecaphytosphingosine.

ASABF, a novel cysteine-rich antibacterial peptide isolated from the nematode Ascaris suum. Purification, primary structure, and molecular cloning of cDNA.

Previously, we reported antibacterial activity in the body fluid of the nematode Ascaris suum (Kato, Y. (1995) Zool. Sci. 12, 225-230). The antibacterial activity is due to a heat-stable and trypsin-sensitive molecule that was designated as ASABF (A. suum antibacterial factor). In the present study, the purification, determination of primary structure, and cDNA cloning of ASABF were carried out. The mature peptide of ASABF is a basic peptide consisting of 71 residues and containing four intramolecular disulfide bridges. The amino acid sequence of a precursor for ASABF, deduced from a cDNA clone, indicates that flanking peptides both at the N terminus and at the C terminus are eliminated by processing. ASABF exhibits potent antibacterial activity particularly against Gram-positive bacteria. ASABF has several features that resemble those of insect/arthropod defensins, whereas the statistical significance of the similarity is not observed on comparison of amino acid sequences. A search of data bases revealed ASABF homologues in Caenorhabditis elegans.

Cloning of a cDNA encoding the small subunit of cytochrome b558 (cybS) of mitochondrial fumarate reductase (complex II) from adult Ascaris suum.

Complex II in the mitochondria of the adult parasitic nematode, Ascaris suum, exhibits high fumarate reductase activity in addition to succinate dehydrogenase activity and plays a key role in the anaerobic energy metabolism of the worm. In this study, the amino acid sequence of the small subunit of cytochrome b558 (cybS) in adult complex II was deduced from the cDNA isolated by immunoscreening an A. suum muscle cDNA library. Histidine residues, which are possible heme axial ligands in cytochrome b558, were found in the second transmembrane segment of the subunit. This is the first report of the primary structure of the small subunit in the two-subunit cytochrome b in mitochondrial complex II from a multicellular eukaryote.

Caenorhabditis elegans UBC-1, a ubiquitin-conjugating enzyme homologous to yeast RAD6/UBC2, contains a novel carboxy-terminal extension that is conserved in nematodes.

The RAD6/UBC2 gene from Saccharomyces cerevisiae encodes a ubiquitin-conjugating enzyme involved in DNA repair, induced mutagenesis, and sporulation. Here we report the isolation and characterization of the Caenorhabditis elegans RAD6 homolog designated ubc-1. Ubc-1 encodes a 21.5-kD protein that shares considerable identity with RAD6 (66%) as well as with other RAD6 homologs, including Schizosaccharomyces pombe rhp6+ (70%), Drosophila melanogaster Dhr6 (83%), and the two human homologs HHR6A and HHR6B (84% and 83%, respectively). However, UBC-1 is distinct in being the only known RAD6 homolog, other than RAD6 itself, with a carboxy-terminal extension. Analysis of UBC-1 homologs from C. briggsae and Ascaris suum show that the presence of the carboxy-terminal extension is conserved in nematodes. When constitutively expressed from the yeast promoter ADH1, ubc-1 complements the DNA repair functions in a S. cerevisiae rad6 delta mutant. Surprisingly, ubc-1 fails to complement the sporulation function of RAD6, despite its possession of an acidic carboxy-terminal tail. C. elegans UBC-1 is capable of forming a thiol-ester bond with ubiquitin, but, unlike RAD6, is unable to transfer ubiquitin to histone H2B in vitro. Both cis and trans splicing are involved in the maturation of the ubc-1 transcript. The presence of the SL2 trans-splice leader in the ubc-1 transcript suggests that ubc-1 may be co-transcribed as part of a polycistronic message.

Subunit interactions in Ascaris hemoglobin octamer formation.

The oxygen-avid, perienteric hemoglobin of Ascaris is a homooctamer. Each subunit contains two tandem globin domains that are highly homologous with the exception of a charged COOH-terminal extension. In solution, recombinant domain one (D1) exists as a monomer, whereas recombinant domain two with the COOH-terminal tail (D2) is primarily an octamer. To examine the role of the COOH-terminal extension in Ascaris hemoglobin multimer formation, we attached the tail to the monomeric, heme-containing proteins, myoglobin and D1; neither construct was capable of multimer formation. Additionally, we removed the tail from both full-length Ascaris hemoglobin and D2. This substantially decreased, but did not eliminate, multimerization. We further characterized subunit interactions by disrupting full-length hemoglobin multimers with the chaotropic salt, NaSCN, which yielded intermediate oligomers. In solution, D2 demonstrated a greater propensity to dissociate than full-length hemoglobin, indicating that D1 contributes to octamer stability. D1 formed a weak dimer in its crystal; thus, we analyzed interactions along the subunit interface. Hydrogen bonds as well as hydrophobic and electrostatic forces appeared to contribute to dimer formation. Amino acid substitutions along this interface in D2 are predicted to enhance subunit interactions for that domain. Our studies reveal that the COOH-terminal tail is necessary, but not sufficient, for efficient octamer formation. Other regions, possibly with the E- and F-helices and AB loops of both domains, appear to be important for Ascaris hemoglobin octamer formation.

Structural characteristics of the Ascaris allergen, ABA-1.

The structure of the Ascaris allergen, ABA-1 was characterized at several levels. Purified allergen monomers eluted from reducing PAGE were found to reassociate into dimers in phosphate buffered saline containing 0.9 mM Ca2+. This association may involve the formation of disulfide bonds between monomers. The primary amino acid sequence was used to predict secondary structure and compare the allergen to other known proteins sequences. ABA-1 appears to be highly helical protein of two domains. Sequence analysis reveals short regions (25 amino acids) of high homology (76%) between ABA-1 and the major body wall myosin of Onchocerca volvulus. In addition, ABA-1 has sequence similarity to a family of EF-hand containing calcium binding proteins called S100 proteins. The dimerization and two-domain structure of ABA-1 is consistent with the possibility that ABA-1 is a member of the S100 family of calcium binding proteins.

Polar zippers: their role in human disease.

Ascaris hemoglobin consists of 8 subunits, each of which contains a C-terminal peptide with the sequence Glu-Glu-Lys-His repeated 4 times. When plotted on a beta-strand, this sequence leads to alternate lysines and glutamates on one side of the strand, and alternate glutamates and histidines on the other side, suggestive of a polar zipper that links the subunits together. A computer search of the protein database showed that the same or similar sequences also occur in other proteins. Some contain long repeats of Asp-Arg or Glu-Arg, among them the small nuclear ribonucleo-U1 70K protein, which is an autoantigen in systemic lupus erythematosis. These repeats appear to constitute the dominant epitopes in the autoimmune reaction. Single chains with Asp-Arg repeats may form alpha-helices in which alternate positively charged ridges and negatively charged grooves compensate each other. Several separate chains with Asp-Arg repeats could compensate each other's charges optimally by zipping together to beta-sheets. Several homeodomains of Drosophila, as well as the human transcription factor SP1, contain repeats of glutamines. Molecular modeling, circular dichroism, and electron and X-ray diffraction studies of a synthetic poly(L-glutamine) showed that it forms beta-sheets held together by hydrogen bonds between the main-chain and side-chain amides. Published data suggest that the function of these glutamine repeats consists of joining essential transcription factors bound to distant segments of DNA.(ABSTRACT TRUNCATED AT 250 WORDS)

Formation of two hydrogen bonds from the globin to the heme-linked oxygen molecule in Ascaris hemoglobin.

We have tried to find out why Ascaris hemoglobin has such an exceptionally high oxygen affinity (P50 approximately 0.004 mmHg; 1 mmHg = 133 Pa). Following Kloek et al., we have synthesized the N-terminal globin domain of Ascaris hemoglobin in Escherichia coli [Kloek, A. P., Yang, J., Mathews, F. S. & Goldberg, D. (1993) J. Biol. Chem. 268, 17669-17671]. Like Kloek et al., we found its oxygen affinity to be as high as that of native Ascaris hemoglobin. We thought that this high affinity might be due to the heme-bound oxygen molecule being stabilized by two hydrogen bonds from the globin instead of the usual one. Ascaris hemoglobin has a distal glutamine instead of the more usual histidine as one of the potential hydrogen bond donors. In addition, it contains a tyrosine at position 10 of B helix (B10) in place of the leucine generally found there in vertebrate myoglobins and hemoglobins. Following the discovery of Carver et al. that sperm whale myoglobin with the replacement of leucine B10 by phenylalanine has a raised oxygen affinity, we have replaced tyrosine B10 in the N-terminal domain of Ascaris hemoglobin by either leucine or phenylalanine [Carver, T. E., Brantley, R. E., Jr., Singleton, E. W., Arduini, R. M., Quillin, H. L., Phillips, G. N., Jr., & Olson, J. S. (1992) J. Biol. Chem. 267, 14443-14450]. Either of these replacements lowered the oxygen affinity about 100-fold, to the same level of that of human alpha-globin chains. These results are consistent with a hydrogen bond linking the tyrosine hydroxyl to the heme-linked oxygen, with a bond energy of 2.7 kcal/mol.

Brugia pahangi and Brugia malayi: a surface-associated glycoprotein (gp15/400) is composed of multiple tandemly repeated units and processed from a 400-kDa precursor.

The cuticle of filarial nematode parasites contains distinct and separable sets of soluble and structural proteins. Surface-labeling techniques have previously identified a soluble protein complex in adult stage Brugia which ranges in molecular weight from 15 to 200 kDa. Using an antiserum directed to the 15-kDa basal subunit of this complex, we show here that this complex is synthesized and processed from a single, very large precursor protein with a molecular weight of approximately 400 kDa. Molecular cloning, sequencing, and Southern analysis indicates that the protein is encoded by a single gene composed predominantly of approximately 20 tandemly repeated segments of 396 bp. The two complete copies of these repeated segments in our cDNA sequence are identical. Each subunit of 132 amino acids bears a consensus site for N-linked glycosylation, and glycosidase treatment indicates that this corresponds to an oligosaccharide side chain of 2 kDa. The protein displays no significant homology to sequences lodged in databases corresponding to molecules of known function. Nevertheless, a significant similarity (19/41 residues) is observed with the N-terminal sequence of a protein termed ABA-1, an allergen from Ascaris.

The primary structure of TE-6: a novel neuropeptide from the nematode Ascaris suum.

Extensive immunoreactivity (IR) towards a hexapeptide (sequence KGQELE), which flanks the C-terminus of the pancreastatin sequence in rat chromogranin A (CGA), is found throughout the nervous system of the nematode parasite Ascaris suum. The peptide IR was purified from the gonoduct of the parasite and found to have the sequence TKQELE. This peptide, designated TE-6, has some C-terminal homology with several regions of the CGA molecule. However, TE-6 was the only peptide isolated suggesting that either the nematode does not possess CGA, or that the -ELE regions of parasite CGA-like peptides which would be larger than TE-6 are not accessible to the antiserum in RIA, or are not being successfully extracted from the parasite. The N-terminus of TE-6 has little homology with any of the sequences preceding -ELE regions in CGA. This, and the fact that the tissue from which TE-6 was isolated does not contain IR towards another, highly conserved, region of the CGA molecule (WE-14) suggests that TE-6 may belong to a new class of regulatory peptide unrelated to CGA.

Ascaris suum: are trypsin inhibitors involved in species specificity of Ascarid nematodes?

Inhibitors of porcine trypsin were prepared from aqueous extracts of the parasitic nematodes Ascaris suum (hogs) and Ascaris lumbricoides (human). In this study three experiments were performed. (1) Polyclonal antibodies were prepared against one isoform of trypsin inhibitor from each parasitic nematode. Each antibody reacted with all isoforms from itself as well as all isoforms from the other parasite. (2) Association equilibrium constants were measured by titrating host trypsins (porcine or human) with the isoforms of trypsin inhibitors from A. suum and A. lumbricoides. While three of the combinations formed tight complexes that can be precipitated, the fourth complex, A. suum trypsin inhibitor-human trypsin has a Ka that is a 300 to 1000 times weaker interaction than the three other titration pairs. (3) Live A. suum worms were incubated in isosmotic media that contained either porcine trypsin or human trypsin. A suum worms survived in porcine trypsin and in the controls but were killed and digested after exposure for 5 days in human trypsin. The first experiment suggests that the trypsin inhibitors from A. suum and A. lumbricoides have similar epitopes, while the second experiment suggests that there are differences near the reactive site of the inhibitors. The consequences of these differences are dramatically demonstrated by the third experiment in which live A. suum worms in the presence of human trypsin die and are digested but those in porcine trypsin survive. These experiments suggest that in order to parasitize a host, a nematode requires a complement of protease inhibitors that interact strongly with those host proteases that are in their environment.

Protein chromatographic study on adult Ascaris lumbricoides, Ascaris vitulorum and Toxocara canis.

Chromatographic analysis using Sephacryl S-300 was done on protein extract of adult Ascaris lumbricoides, A. vitulorum and Toxocara canis worms. Six fractions were separated from both Ascaris species and nine from T. canis. Fractions revealed a variety of molecular weights in relation to the three species of worms that ranged from 6,000-70,000 daltons. Crude extract of T. canis showed cross reaction with both species of Ascaris sera using double gel diffusion, while no reaction was obtained using a partially purified antigen.

Structure and macromolecular assembly of two isoforms of the major sperm protein (MSP) from the amoeboid sperm of the nematode, Ascaris suum.

Ascaris sperm are amoeboid cells that crawl by extending pseudopods. Although amoeboid motility is generally mediated through an actin-based cytoskeleton, Ascaris sperm lack this system. Instead, their major sperm protein (MSP) forms an extensive filament system that appears to fulfil this function. Because their motility appears to be essentially the same as that of their actin-rich counterparts, Ascaris sperm offer a simple alternative system for investigation of the molecular mechanism of amoeboid movement. To examine the structure and composition of the cytoskeleton, we stabilized the extremely labile native MSP filaments by detergent lysis of sperm in the presence of either glutaraldehyde or polyethylene glycol (PEG). Biochemical analysis showed that the cytoskeleton contained two isoforms of MSP, designated alpha- and beta-, that we purified and sequenced. Both contain 126 amino acids and have an acetylated N-terminal alanine, but differ at four residues so that alpha-MSP is 142 Da larger and 0.6 pH unit more basic than beta-MSP. Neither isoform shares sequence homology with other cytoskeletal proteins. In ethanol, 2-methyl-2,4-pentanediol (MPD), and other water-miscible alcohols each isoform assembled into filaments 10 nm wide with a characteristic substructure repeating axially at 9 nm. These filaments were indistinguishable from native fibers isolated from detergent-lysed sperm. Pelleting assays indicated a critical concentration for assembly of 0.2 mM for both isoforms in 30% ethanol, but alpha-MSP formed filaments at lower solvent concentration than beta-MSP. When incubated in polyethylene glycol, both isoforms formed thin, needle-shaped crystals that appeared to be constructed from helical fibers, with a 9 nm axial repeat that matched that seen in isolated filaments. These crystals probably contained a parallel array of helical filaments, and may enable both the structure of MSP molecules and their mode of assembly into higher aggregates to be investigated to high resolution.