Purification and characterization of alpha-amylases from the intestine and muscle of ascaris suum (Nematoda)

Alpha-Amylase (EC 3.2.1.1) was purified from the muscle and intestine of the parasitic helminth of pigs Ascaris suum. The enzymes from the two sources differed in their properties. Isoelectric focusing revealed one form of a-amylase from muscles with pl of 5.0, and two forms of amylase from intestine with pI of 4.7 and 4.5. SDS/PAGE suggested a molecular mass of 83 kDa and 73 kDa for isoenzymes of a-amylases from intestine and 59 kDa for the muscle enzyme. Alpha-Amylase from intestine showed maximum activity at pH 7.4, and the enzyme from muscle at pH 8.2. The muscle enzyme was more thermostabile than the intestinal alpha-amylase. Both the muscle and intestine amylase lost half of its activity after 15 min at 70 degrees C and 50 degrees C, respectively. The Km values were: for muscle amylase 0.22 microg/ml glycogen and 3.33 microg/ml starch, and for intestine amylase 1.77 microg/ml glycogen and 0.48 microg/ml starch. Both amylases were activated by Ca2+ and inhibited by EDTA, iodoacetic acid, p-chloromercuribenzoate and the inhibitor of a-amylase from wheat. No significant differences were found between the properties of a-amylases from parasites and from their hosts.     

Isolation and partial characterization of trehalase from Ascaris muscle.

The tissues of female Ascaris suum were assayed for alpha,apha'-glucoside 1-D-glucohydrolase (trehalase) activity. A soluble from of the enzyme was isolated from muscle tissue and purified approximately 37-fold. The enzyme was specific for trehalose as substrate. The pH optimum for enzymatic activity was found to be 6.0, and the apparent Km for trehalose was estimated to be 2.1 x 10-4 M. The product of the reaction was identified as D-glucose by chemical, chromatographic and enzymatic methods.     

Copper-zinc superoxide dismutase fromAscaris suum (Nematoda): Purification and characterization

Copper-zinc superoxide dismutase fromAscaris suum (Nematoda) was purified in a new, more efficient, and faster manner. The process included differential centrifugation, fractionation with ammonium sulfate, and sodium dodecyl sulfate-polyacrylamide electrophoresis, yielding a 340-fold purification (specific activity of 47 units/mg). Optimal storage conditions, optimal pH range, thermostability, molecular weight and ultravioltet-visible absorption spectrum of the enzyme are described, and a new enzymatic model for pharmacological screening is suggested.Abbreviations (SOD) Superoxide dismutase - (EDTA) Ethylenediaminetetraacetic acid - (SDS) Sodium dodecyl sulfate - (NBT) p-nitrotetrazolium blue - (UV) Ultraviolet     

Purification and properties of fructose diphosphate aldolase from Ascaris suum muscle

A fructose diphosphate aldolase has been isolated from ascarid muscle and crystallized by simple column chromatography and an ammonium sulfate fractionation procedure. It was found to be homogeneous on electrophoresis and Sephadex G-200 gel filtration. This enzyme has a fructose diphosphate/fructose 1-phosphate activity ratio close to 40 and specific activity for fructose diphosphate cleavage close to 11. K_m values of ascarid aldolase are 1 × 10⁻⁶m and 2 × 10⁻³m for fructose diphosphate and fructose 1-phosphate, respectively. The enzyme reveals a number of catalytic and molecular properties similar to those found for class I fructose diphosphate aldolases. It has C-terminal functional tyrosine residues, a molecular weight of 155,000, and is inactivated by NaBH₄ in presence of substrate. Data show the presence of two types of subunits in ascarid aldolase; the subunits have different electrophoretic mobilities but similar molecular weights of 40,000. Immunological studies indicate that the antibody-binding sites of the molecules of the rabbit muscle aldolase A or rabbit liver aldolase B are structurally different from those of ascarid aldolase. Hybridization studies show the formation of one middle hybrid form from a binary mixture of the subunits of ascarid and rabbit muscle aldolases. Hybridization between rabbit liver aldolase and ascarid aldolase was not observed. The results indicate that ascarid aldolase is structurally more related to the mammalian aldolase A than to the aldolase B.     

Amino acid and lipid composition of refringent granules from the ameboid sperm of Ascaris suum (Nematoda)

Transformation of the spermatozoon of Ascaris suum from a spheroidal to an ameboid cell is associated with the formation of a motile pseudopodium and coalescence of the intracellular refringent granules. The pseudopodia of the ameboid spermatozoa contain filaments organized into dense patches, bundles, web-like or lace-like networks, as observed by electron microscopy. The morphology and chemistry of the refringent granules were investigated in subcellular fractions enriched for these structures. Isolated refringent granules were heterogeneous in size measuring from 0.5 X 0.6 to 2.3 X 3.5 microns. Each granule is surrounded by a 110 A thick layer. During fusion, the surfaces of the refringent granules form small extensions resembling micropodia. The process of fusion occurs at many sites on a given granule and simultaneous fusion of several granules was commonly observed. Amino acid analyses of the refringent granule proteins (RGP's) indicated: they are rich in aspartic acid or asparagine (48%), leucine (10%), serine (19%) and aromatic amino acids (11%). Gas-liquid chromatographic analyses of alditol acetate derivatives of monosaccharides released by mild acid hydrolysis showed the predominant sugars to be glucose (7.3 micrograms/mg protein), galactose (9.2 micrograms/mg) and N-acetylglucosamine (5.5 micrograms/mg). Lipid analyses indicated a complex mixture of glycerides, ascarosides and waxes, together with a major component that resembled free fatty acid in mobility on TLC.     

Amino acid and lipid composition of refringent granules from the ameboid sperm of Ascaris suum (Nematoda)

Summary Transformation of the spermatozoon of Ascaris suum from a spheroidal to an ameboid cell is associated with the formation of a motile pseudopodium and coalescence of the intracellular refringent granules. The pseudopodia of the ameboid spermatozoa contain filaments organized into dense patches, bundles, web-like or lace-like networks, as observed by electron microscopy.The morphology and chemistry of the refringent granules were investigated in subcellular fractions enriched for these structures. Isolated refringent granules were heterogeneous in size measuring from 0.5×0.6 to 2.3×3.5 m. Each granule is surrounded by a 110 Å thick layer. During fusion, the surfaces of the refringent granules form small extensions resembling micropodia. The process of fusion occurs at many sites on a given granule and simultanenous fusion of several granules was commonly observed.Amino acid analyses of the refringent granule proteins (RGP's) indicated: they are rich in aspartic acid or asparagine (48%), leucine (10%), serine (19%) and aromatic amino acids (11%). Gas-liquid chromatographic analyses of alditol acetate derivatives of monosaccharides released by mild acid hydrolysis showed the predominant sugars to be glucose (7.3 g/mg protein), galactose (9.2 g/mg) and N-acetylglucosamine (5.5 g/mg). Lipid analyses indicated a complex mixture of glycerides, ascarosides and waxes, together with a major component that resembled free fatty acid in mobility on TLC.     

Purification and characterization of phosphoenolpyruvate carboxykinase from the parasitic helminth Ascaris suum

Phosphoenolpyruvate carboxykinase has been purified from homogenates of Ascaris suum muscle strips to apparent homogeneity as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The purification is a three-step procedure which yields pure enzyme in milligram quantities with good yield. The subunit molecular weight of the Ascaris enzyme is between 75,000 and 80,000. The native molecular weight is 83,000 as determined by gel filtration. The kinetic constants for substrates of the carboxylation reaction were determined and compared to those measured for the avian liver enzyme. From kinetic studies it appears likely that two separate roles for divalent metal ions exist in the catalytic process. Studies conducted with Mn2+ or with micromolar concentrations of Mn2+, in the presence of millimolar concentrations of Mg2+ suggest that Mn2+ but not Mg2+ binds directly to and activates the enzyme while either Mn2+ or Mg2+ may bind to the nucleotide resulting in the metal-nucleotide complex. The metal-nucleotide is the active form of the substrate for the reaction. In the presence of Mg2+, an increase in the Mn2+ concentration results in a decrease in the Km for P-enolpyruvate suggesting a direct role for Mn2+ stimulation and regulation of activity. The concentrations of Mn2+ and Mg2+ in Ascaris muscle strips were determined by atomic absorption spectroscopy and support the proposed hypothesis of a specific Mn2+ activation of the enzyme. The nucleotides ATP and ITP act as competitive inhibitors against GTP with KI values of 0.50 and 0.75 mM, respectively. ITP is a competitive inhibitor against both IDP and P-enolpyruvate, suggesting overlapping binding sites for the two substrates on the enzyme.     

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(β1-1)ceramide, Man(β1-4)Glc(β1-1)ceramide, GlcNAc(β1-3)Man(β1-4)Glc(β1-1)ceramide and Gal(α1-3)GalNAc(β1-4)GlcNAc(β1-3)Man(β1-4)Glc(β1-1)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. Abbreviations: CDH, ceramide dihexoside; Cer, ceramide; CMH, ceramide monohexoside; CPH, ceramide pentahexoside; CTH, ceramide trihexoside; CTetH, ceramide tetrahexoside; Hex, hexose; HexNAc, N-acetylhexosamine; HPTLC, high-performance thin-layer chromatography; LSIMS, liquid secondary-ion mass spectrometry; MALDI-TOF-MS, matrix-assisted laser desorption/ionization time-of-flight mass spectrometry; N-, Nz- and A-glyco(sphingo)lipids, neutral, neutralzwitterionic and acidic glyco(sphingo)lipids, respectively This revised version was published online in November 2006 with corrections to the Cover Date.     

Purification and properties of an acyl CoA transferase from Ascaris suum muscle mitochondria

An acyl CoA transferase has been purified to electrophoretic homogeneity from the soluble compartment of Ascaris suum muscle mitochondria. From SDS-PAGE, isoelectric focusing and molecular exclusion chromatography, homogeneity was confirmed and the enzyme appears to be composed of two similar or identical subunits of apparent mol. wts of 50,000 resulting in an apparent mol. wt of 100,000 for the holoenzyme. The apparent isoelectric point was 5.6 +/- 0.1 by both chromatofocusing columns and slab gel isoelectric focusing. The transferase was relatively specific for the short, straight-chain acyl CoA donors as well as the CoA acceptors, being active on acetyl CoA, propionyl CoA, butyryl CoA, valeryl CoA and hexanoyl CoA as donors to acetate and propionate. Neither succinyl CoA nor succinate were appreciably active as CoA donor or acceptor, respectively. This enzyme cannot serve physiologically to activate succinate for decarboxylation to propionate, but may serve to ensure a supply of propionyl CoA which appears to be required in catalytic amounts for the decarboxylation of succinate.     

Phosphofructokinase from Ascaris suum. Purification and properties

A rapid and efficient procedure has been developed to purify phosphofructokinase from the muscle of the parasitic roundworm, Ascaris suum. The procedure can be accomplished in 1 day with a 420-fold purification and a 60% yield. The enzyme was shown to be homogeneous by two-dimensional electrophoresis, Sepharose 6B column chromatography, and high performance liquid chromatography utilizing a size exclusion column. The subunit molecular weight of the enzyme was found to be 95,000 by electrophoresis in the presence of sodium dodecyl sulfate. In solutions of low ionic strength, the native enzyme aggregated to species of higher molecular weight than did the rabbit muscle phosphofructokinase. In the presence of 0.2 M (NH4)2SO4, the minimum native molecular weight was determined to be 398,000 by high performance liquid chromatography and Sepharose 6B column chromatography. Therefore, the enzyme appears to be a tetramer with identical or near-identical subunits. The apparent isoelectric point of the enzyme was shown to be 7.3 to 7.4 by both column and gel isoelectric focusing. Amino acid analysis revealed a lower number of the aromatic residues Phe, Tyr, and Trp than in the rabbit muscle enzyme and this is in agreement with the lower extinction coefficient of E1%280 nm = 6.5. Analysis of the purified enzyme revealed 7.4 +/- 0.6 mol of phosphate/mol of enzyme.     

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.     

In vitro activation and behavior of the ameboid sperm of Ascaris suum (Nematoda)

Summary A system is described for the study of activation and motility of Ascaris spermatozoa in vitro. Activation was accomplished by addition of the sperm-activating substances (SAS), extracted from the male accessory gland, to cells incubated in phosphate-buffered saline (pH 7.4) at 37–39° C under anaerobic conditions (95% N₂, 5% CO₂). Activation is characterized by a change from spherical to ameboid shape with coalescence of the refringent granules. The normal ameboid spermatozoa bear several stubby and needle-like filopodia at the lamellipodial margin. Within the lamellipodium are bundles of microfilament-like structures extending toward the pseudopodial membrane and concentrating within the needle-like filopodia. These filopodia exhibit a pendulous, sweeping motion with subsequent retraction and disappearence within the main lamellipodium. Membranes of the ameboid cells interact at the pseudopodial regions with partial fusion, as suggested by apparent membrane breakdown between interdigitating portions of the pseudopodia. Activation is complete in 5–15 min, is totally inhibited at 4° C and/or by an atmospheric environment, but can be reinitiated by transfer to anaerobic conditions at 22–9° C. Activation also requires favorable pH (6.8–8.7) and continual exposure to sufficiently high sodium concentrations (134–154mM), i.e., lowering of sodium concentration to 10 mM causes irreversible inactivation. Sodium may be replaced by potassium or lithium but not by Tris or sucrose. Proteinases (10 g/ml) can act as activators even though SAS lack detectable proteolytic activity against azoalbumin, azocasein, TAME and BTEE and SAS activation was not inhibited by TLCK or soybean trypsin inhibitor.Adult Ascaris suum were provided through the generosity of Wilson and Company, Cedar Rapids, Iowa, U.SA. This study was supported by grant number 5T01 HD00152 and postdoctoral fellowship 1F 32AI05646 from the National Institute of Health, U.S.A.     

Subcellular fractions and the refringent granules of the spermatozoa of Ascaris suum (Nematoda)

Summary Six subcellular fractions were isolated by differential centrifugation of the homogenate of spermatozoa of Ascaris suum. The cellular constituents of pelleted fractions, as identified by electron microscopy, were membranes and membranous organelles (fraction A1), microsomal (A2), cytoplasmic (A3), large refringent granules (B1), small refringent granules (B2) and a detergent-soluble fraction (B3).Polypeptide analysis by SDS-PAGE showed that the 18,400-dalton band, one of the major spermatozoan proteins, is detectable in all of the fractions. However, the cytoplasmic (A1) and refringent-granule (B1) fractions contained the highest level.The isolated refringent granules consisted of 2–6 % lipid while the nonlipid fraction formed an insoluble matrix with a fibrillar network morphology. This fibrillar matrix contained three polypeptides of small molecular weight (7,000–14,000) in addition to the 18,400-dalton polypeptide. These small polypeptides (7,000–14,000 MW) are detectable only in fractions of the refringent granules and are therefore called the refringent-granule proteins (RGP). These RGP are sensitive to tryptic hydrolysis and have solubility properties similar to the protein, ascaridine.Adult Ascaris suum were generously provided by Wilson and Company, Cedar Rapids, Iowa. This study was supported by postdoctoral fellowship 5F32AI05646 from NIH. The assistance of Mr. Douglas Wood is gratefully acknowledged     

Biochemical studies on the muscle microsomes of Ascaris lumbricoides var. suum. II. Purification and characterization of b-type cytochrome and NADH-ferricyanide reductase from Ascaris muscle microsomes.

A b-type cytochrome and NADH-ferricyanide (FC) reductase were solubilized from Ascaris muscle microsomes by detergents and purified by column chromatography. The purified b-type cytochrome displayed absorption bands at 560 (alpha-peak), 525 (beta-peak), and 424 nm (gamma-peak), with a marked shoulder at 555 nm in the reduced from, 415 nm (gamma-peak) in the oxidized form. This absorption spectrum was different from that of rat liver microsomal cytochrome b5. The molecular weight was estimated to be about 100,000 by SDS-polyacrylamide gel electrophoresis, and the absorption spectrum of alkaline pyridine ferrohemochrome suggested that the prosthetic group of this cytochrome is protoheme. The molecular weight of the purified NADH-FC reductase was estimated to be about 55,000 by SDS-polyacrylamide gel electrophoresis. The purified reductase required NADH as a specific electron donor. The reductase efficiently reduced some redox dyes with NADH, but the reduction of cytochrome c was much slower. The purified reductase, like the membrane-bound reductase, was not inhibited by thiol reagents.     

Purification and characterization of acid trehalase from the yeast suc2 mutant

Acid trehalase was purified from the yeast suc2 deletion mutant. After hydrophobic interaction chromatography, the enzyme could be purified to a single band or peak by a further step of either polyacrylamide gel electrophoresis, gel filtration, or isoelectric focusing. An apparent molecular mass of 218,000 Da was calculated from gel filtration. Polyacrylamide gel electrophoresis of the purified enzyme in the presence of sodium dodecyl sulfate suggested a molecular mass of 216,000 Da. Endoglycosidase H digestion of the purified enzyme resulted after sodium dodecyl sulfate gel electrophoresis in one distinct band at 41,000 Da, representing the mannose-free protein moiety of acid trehalase. The carbohydrate content of the enzyme was 86%. Amino acid analysis indicated 354 residues/molecule of enzyme including 9 cysteine moieties and only 1 methionine. The isoelectric point of the enzyme was estimated by gel electrofocusing to be approximately 4.7. The catalytic activity showed a maximum at pH 4.5. The activity of the enzyme was not inhibited by 10 mM each of HgCl2, EDTA, iodoacetic acid, phenanthrolinium chloride or phenylmethylsulfonyl fluoride. There was no activation by divalent metal ions. The acid trehalase exhibited an apparent Km for trehalose of 4.7 +/- 0.1 mM and a Vmax of 99 mumol of trehalose min-1 X mg-1 at 37 degrees C and pH 4.5. The acid trehalase is located in the vacuoles. The rabbit antiserum raised against acid trehalase exhibited strong cross-reaction with purified invertase. These cross-reactions were removed by affinity chromatography using invertase coupled to CNBr-activated Sepharose 4B. Precipitation of acid trehalase activity was observed with the purified antiserum.     

Comparative purification and characterization of invertebrate muscle glycogen synthase from the porcine parasite Ascaris suum

Glycogen synthase has been purified from the obliquely striated muscle of the swine parasite Ascaris suum. The muscle contains a concentration of glycogen synthase and glycogen which is 20-fold and 15-fold, respectively, greater than rabbit skeletal muscle. The enzyme could not be solubilized with salivary amylase, but partial solubilization was achieved by activation of endogenous phosphorylase. The enzyme was purified to 85-90% homogeneity (specific activity = 4.3 units/mg) by DEAE-cellulose, Sepharose 4B, and glucosamine 6-phosphate chromatography. The purified glycogen synthase was substantially similar to rabbit skeletal muscle enzyme with respect to Mr (gel electrophoresis and gel filtration), pH dependence, aggregation properties, temperature dependence, and kinetic constants for substrates and activators. Glycogen synthase I was converted to glycogen synthase D by the cyclic AMP-dependent protein kinase. The cyclic AMP-dependent protein kinase catalyzed the incorporation of 1.3 mol of phosphate into each glycogen synthase I subunit and the concomitant interconversion to glycogen synthase D. Since glycogen is the sole fuel utilized by this organism during nonfeeding periods of the host, the characterization of this enzyme provides further insight into the regulatory mechanisms which determine glycogen turnover.