Neuraminidase fromPasteurella haemolytica

A soluble extracellular antigen produced byPasteurella haemolytica serotype 1 possesses neuraminidase activity. The metal ions Mn²⁺, Mg²⁺, and Ca²⁺ stimulate enzyme activity, while the heavy metal ions Hg²⁺ and Fe³⁺ inhibit neuraminidase activity. Extensive dialysis of the enzyme with 50 mM ethylenediaminetetraacetic acid does not result in loss of enzyme activity. Antiserum prepared againstPasteurella haemolytica serotype 1 inhibits neuraminidase activity 2.0- to 2.7-fold, suggesting that neuraminidase is part of the antigenic complex. Initial rate kinetics of neuraminidase reveals that the Michaelis constant for fetuin is 3.84 mg/ml (96 M) and the maximal velocity (V _max) is 0.53 mmol/min/mg of protein.     

Lectins as markers of rumen epithelial cell differentiation

Summary Lectins of different carbohydrate specificities (GNA (Galanthus nivalis), con A (Canavalia ensiformis), VFL (Vicia faba), PSL (Pisum sativum), LCA (Lens culinaris), PNA (Arachis hypogaea; with or without prior neuraminidase treatment), WGA (Triticum vulgare), SBA (Glycine max), UEA-I (Ulex europaeus), LPA (Limulus polyphemus), BS-I B₄ (Bandeiraea simplicifolia, isolectin B₄)) were explored for use as differentiation markers of rumen epithelial cellsin vivo andin vitro. Lectins specific for mannose (GNA), mannose/glucose (con A, VFL, PSL and LCA),N-acetylglucosamine (WGA) or forN-acetylneuraminic acid (LPA) reacted generally with all types of rumen epithelial cell from both rumen tissue and cell culture. They were, therefore, not suitable markers of epithelial differentiation. SBA was unsuitable because, although it reacted with both tissue and cultured rumen epithelial cells, it was also bound to non-stratified areas of primary rumen epithelial cell cultures. Both BS-I B₄ and PNA (after neuraminidase treatment) had to be ruled out because they did not react with differentiated rumen tissue epithelial cells, although they did bind to both stratified and non-stratified cultured cells. In contrast, UEA-I reacted strongly with differentiated rumen epithelial cells both from rumen tissue and cell cultures and therefore appears to be a good general marker for rumen epithelial cell differentiation.     

Radiation inactivation of enzymes at low dose rates: Identical molecular weights of rat liver cytosolic and lysosomal neuraminidases

A low-dose-rate gamma source (⁶⁰Co) was calibrated with enzymes of known radiation inactivation behaviors and used for molecular weight determination of rat liver neuraminidase (EC 3.2.1.18). The method allows direct comparison of radiation inactivation of standard and unknown enzymes under identical experimental conditions. The membrane-bound lysosomal neuraminidase had the same molecular weight (M_r = 56,000 ± 8500) as the soluble cytosolic neuraminidase (M_r = 56,000 ± 7000) although they differ in their kinetic properties and substrate specificity.     

链球菌神经氨酸酶的作用机制及酶活性的测定技术

神经氨酸酶不仅存在于流感病毒,在细菌中也有分布。细菌的神经氨酸酶可裂解宿主体内糖结合物末端的神经氨酸残基,有助于细菌实现在宿主体内的定殖、穿透和扩散,是细菌重要的毒力因子之一。链球菌是自然界广泛存在的人畜共患的病原菌,在多种链球菌中均可检测出神经氨酸酶。肺炎链球菌的神经氨酸酶研究最为透彻,该菌可产生3种神经氨酸酶(NanA,NanB,NanC),NanA不但可以发挥酶的催化作用,分解唾液酸残基,暴露细菌的黏附受体,还能不依赖酶活基团,辅助细菌感染宿主细胞;NanB催化后产物可作为细菌的碳源;NanC可辅助细菌入侵脑部。在无乳链球菌和猪链球菌中,神经氨酸酶的活性一直未得到确切的验证,可能是由于它们的荚膜均含有神经氨酸,所以其神经氨酸酶的活性逐渐在进化中丧失。另外一些链球菌,例如化脓链球菌和C、G、L群链球菌,其神经氨酸酶的底物偏好相近,均对唾液类黏蛋白的催化活性较强,利于链球菌在含唾液类黏蛋白的组织中扩散。在口腔链球菌和血链球菌中,神经氨酸酶破坏血液成分中的神经氨酸链。由此可见,神经氨酸酶的特异性催化作用与链球菌在宿主体内的定植部位密切相关。此外,随着科技的发展,对神经氨酸酶的活性检测,也由早期的硫代巴比妥法,转为现在的荧光值和吸光度的测定,更为便捷和敏感。本文旨在对链球菌的神经氨酸酶的作用机制、与毒力关系及酶活测定方法等研究进展作一综述,为从事相关研究的科学工作者提供参考。     

Immunochemical studies of isolated human brain ganglioside components

Abstract— Gangliosides G₁ to G₅ were isolated from human brain by means of TLC and tested with respect to their specificity to antisera against normal brain and Tay-Sachs brain gangliosides by agar double diffusion analysis. Gangliosides G₂ and G₄ gave precipitation reactions with antisera to normal human gangliosides (NHG) while only ganglioside G₆ reacted with antisera to Tay-Sachs gangliosides (TSG). Additional specificity information was also obtained by use of the enzyme neuraminidase for the removal of specific sialic acid (NANA) residues. It was concluded from these data that the specificity of the anti-NHG antibodies is determined by the presence of a galactose (β1, 3) N-acetyl galactos-amine–while that of anti-TSG antibodies is due to a N-acetyl galactosamine (β1, 4) galactose-end sequence. By means of natural compounds of known structure it was found that both the sequence of carbohydrate residues and position of NANA residues in the molecule played a critical role in the formation of precipitation bands with NHG-antisera. This information was utilized to distinguish one isomeric form of disialoganglioside from another, i.e. G₂ from G₃ and to confirm the structure of the trisialoganglioside, G₁. The immunochemical method appears to be a useful one for elucidating structural differences in ganglioside molecules.     

Docking and 3D QSAR study of thiourea analogs as potent inhibitors of influenza virus neuraminidase

Surflex-Dock was applied to study interactions between 30 thiourea analogs and neuraminidase (NA). The docking results showed that hydrogen bonding and electrostatic interactions were highly correlated with the activities of neuraminidase inhibitors (NIs), followed by hydrophobic and steric factors. Moreover, there was a strong correlation between the predicted binding affinity (total score) and experimental pIC₅₀ (correlation coefficient r = 0.870; P < 0.0001). A three dimensional holographic vector of atomic interaction field (3D-HoVAIF) was employed to construct a QSAR model. The r ², q ² and r ² _test values of the optimal QSAR model were 0.849, 0.724 and 0.689, respectively. From the QSAR model, it could be seen that electrostatic, hydrophobic and steric interactions were closely related to inhibitory activity, which was consistent with the docking results. Based on the docking and QSAR results, five new compounds with high predicted activities were designed.     

Activation of T lymphocytes results in an increase inH-2-encoded neuraminidase

The endogenous neuraminidase activity of various mouse lymphoid subpopulations and tissue compartments was examined by a sensitive fluorometric assay. These analyses indicated that activated T lymphocytes possessed a significantly higher level of intracellular neuraminidase than activated B or resting T or B lymphocytes. Examination of the level of neuraminidase in bone marrow, thymus, lymph node, and unfractionated spleen indicated that these lymphoid tissues contained significantly less neuraminidase than was detected in stimulated T cells. Kinetic studies revealed that the majority of the increase in neuraminidase activity occurred between 24 and 48 h following stimulation. Analysis of activated T lymphocytes prepared from a panel of inbred mouse strains indicated that cells from mice of theH-2 ^v haplotype, which possess theNeu-1 ^a allele and are deficient in liver neuraminidase, exhibited a level of activity which was significantly lower than that detected in stimulated T cells from other mouse strains. These results indicate that the endogenous neuraminidase activity of T lymphocytes increases upon stimulation, and that the level of this enzyme activity in lymphoid cells is also controlled by theNeu-1 locus, which is located in theH-2 region of the major histocompatibility complex.Abbreviations used in this paper MHC major histocompatibility complex - LPS lipopolysaccharide - DXS dextran sulfate - IL-2 interleukin 2 - NANA N-acetylneuraminic acid - sIg surface immunoglobulin - Con A concanavalin A - C57BL/10 B10     

Plasmodium berghei: modification of sialic acid on red cells from infected mouse blood

The surface membrane glycoproteins of normal mouse erythrocytes can be labeled by oxidation with either periodate or galactose oxidase in the presence of neuraminidase, followed by reduction with NaB³H₄. Without neuraminidase there is little galactose oxidase-catalyzed labeling of protein. Analysis of labeled proteins by SDS-polyacrylamide gel electrophoresis showed that both methods labeled the same set of glycoproteins. Plasmodium berghei infection dramatically reduced the sialoglycoprotein labeling of red blood cells from infected blood using the periodate/NaB³H₄ method. Provided neuraminidase was present, labeling by the galactose oxidase method gave identical results to normal erythrocytes. We conclude that the glycoprotein sialic acid of uninfected as well as infected red cells is modified during infection such that it is refractory to periodate oxidation. Acylation of the exocyclic hydroxyls of sialic acid is suggested to account for this. Lectin binding and cell agglutination experiments using Limulin, soybean and wheatgerm lectins, and concanavalin A confirmed and extended these observations. The possible implications of these results with regard to anemia induced by malaria are briefly discussed.     

Km values of influenza virus neuraminidases for a new fluorogenic substrate, 4-methylumbelliferone N-acetyl neuraminic acid ketoside.

A fluorogenic substrate of neuraminidase, 4-methylumbelliferone N-acetylneuraminic acid ketoside (MUN), was synthesized. K_m values were obtained for Clostridium perfringens neuraminidase and strains of A- and B-type influenza neuraminidase from chicken red blood cell influenza virus eluates.     

Chemical and histochemical studies of normal and diseased human gastrointestinal tract. II. A comparison between histologically normal small intestine and Crohn's disease of the small intestine

Summary Comparative chemical and histochemical studies were performed on formalin-fixed, surgical specimens of human small intestine from cases of Crohn's disease and normal controls. The sialic acids of the crude glycoproteins isolated from normal ileum were significantly less neuraminidase-susceptible and more C₄ substituted (P<0.01) than those of the glycoproteins isolated either from normal upper small intestine (duodenum and jejunum) or from cases of Crohn's disease of the ileum. Fractionation yielded two major sialic acid-containing fractions, eluting from DEAE-cellulose with 0.2m or 0.3m sodium chloride. Both fractions contained fucose, galactose, glucosamine and galactosamine in addition to sialic acids both with and withoutO-acyl substituents at position C₄ and/or in the side-chain (side-chainO-acylated sialic acids were also detected by histochemical procedures). The fractions differed significantly from one another with respect to the neuraminidase susceptibility of their sialic acids (P<0.01), the percentage of C₄ (P<0.01) and side-chain substituted sialic acids (P<0.05), and the molar fucose-sialic acid ratio (P<0.05). TheO-acyl substitution patterns of the sialic acids of both the 0.2m and 0.3m fractions of the upper small intestine glycoproteins differed significantly from those of the corresponding fractions from normal ileum, while the sialic acids of the 0.2m fractions from Crohn's disease of the ileum differed significantly from normal with respect to neuraminidase susceptibility (P<0.01) and percentage C₄ substitution (P<0.01); the 0.3m fractions differed only in the percentage of sialic acids substituted at C₄. The differences between the sialic acids from the normal and Crohn's disease specimens were shown to be independent of either the anatomical origin of the specimen or the histopathological sub-group of the Crohn's disease specimens; no significant differences were noted between the sub-groups but all the sub-groups differed from normal.     

The binding properties of the H5N1 influenza virus neuraminidase as inferred from molecular modeling

The avian influenza H5N1 virus has emerged as an important pathogen, causing severe disease in humans and posing a pandemic threat. Substrate specificity is crucial for the virus to obtain the ability to spread from avian to human. Therefore, an investigation of the binding properties of ligands at the molecular level is important for understanding the catalytic mechanism of the avian influenza virus neuraminidase and for designing novel and specific inhibitors of H5N1 neuraminidase. Based on the available crystal structure of H5N1, we have characterized the binding properties between sialic acid, methyl 3’sialyllactoside, methyl 6’sialyllactoside and the H5N1 influenza virus neuraminidase using molecular docking and molecular dynamics simulations. Obtained molecular dynamics trajectories were analyzed in terms of ligand conformations, N1-ligand interactions, and in terms of loop flexibility. It was found that in the N1-SA complex the sialic acid ring undergoes a transition from the B _2,5 to the ² C ₅ conformation. However, in the N1-3SL and N1-6SL complexes sialic acid remained in the distorted boat conformation. The obtained results indicate that 3SL has only weak interactions with the 150-loop, whereas the N1-6SL complex shows strong interactions. Most of the differences arise from the various conformations around the glycosidic linkage, between the sialic acid and galactose, which facilitate the above interactions of 6SL with the enzyme, and as a consequence the interactions between the 150- and 430- loops. This finding suggests that the altered flexibility of loops in and around the active site is one of the reasons why the avian N1 preferentially cleaves sialic acid from α-(2-3)-Gal glycoconjugates over α-(2-6)-Gal. These molecular modeling results are consistent with available experimental results on the specificity of N1.     

Analogs of zanamivir with modified C4-substituents as the inhibitors against the group-1 neuraminidases of influenza viruses

Unlike the group-2 neuraminidase, the group-1 neuraminidase of influenza virus possesses a flexible loop (the 150-loop) and a cavity (the 150-cavity) adjacent to the active site, and renders a conformational change from the ‘open’ form to the ‘closed’ form on binding with substrate (sialo-glycoprotein) or inhibitor (e.g., zanamivir). Zanamivir derivative 8a having an extended (piperazinocarbonyl)propyl substituent at the internal N-position of the guanidino group is designed as a possible inhibitor on the basis of computer docking to the open form of N1 subtype neuraminidase. Indeed, compound 8a exhibits strong neuraminidase inhibition and good anti-influenza activity against H1N1 virus with IC₅₀ = 2.15 μM and EC₅₀ = 0.77 μM, respectively. This study may provide a clue to future design of better group-1 neuraminidase inhibitors.     

Sialic acid and the surface charge associated with hyperpolarization-activated,inward rectifying channels

Summary The whole-cell configuration of the patch-clamp technique was used with cultured pacemaker cells from the rabbit sinoatrial node to test the hypothesis that sialic acid residues (NANA) constitute much of the negative surface charge associated with hyperpolarization-activated, inward rectifying channels. Activation-voltage relationships (between –70 and –140 mV) were determined for hyperpolarization-activated (inward rectifying) current (i _f). Addition of 10mm Ca²⁺ shifted the half-activation potential (V _1/2) from –89.5±0.9 mV to –77.9±2.6 mV (P<0.01), confirming the presence of negative fixed charges on the myocytes after 3 to 5 days in culture. Addition of 20mm dimethonium, an organic divalent cation that screens but does not bind to negative surface charge, shiftedV _1/2 from –86.8±1.4 mV to –75.0±1.7 mV (P<0.001) without affecting the amplitude of the current. In contrast, 10mm Ca²⁺ reduced the amplitude ofi _f significantly. Incubation of cells with a highly purified preparation of neuraminidase (0.1–2.0 U/ml, 1 hr, 37°C), an enzyme that selectively removes NANA from glycoproteins and glycolipids, failed to alterV _1/2 or the amplitude ofi _f significantly. Pretreatment of cells with neuraminidase (1.0 U/ml, 1 hr, 37°C) failed to alter the positive shift ofV _1/2 produced by dimethonium. The results suggest that NANA does not constitute the negative surface charge associated with hyperpolarization-activated, inward rectifying channels.     

Purification and properties of a neuraminidase from Streptococcus K 6646

A neuraminidase was purified from the culture filtrate of Streptococcus 6646 (group K) by means of ammonium sulfate fractionation and successive column chromatographies on N-(p-aminophenyl)oxamic acid-substituted Sepharose derivative and p-aminophenyl-2-acetamido-2-deoxy-1-thio-β-d-glucopyranoside-substituted Sepharose derivative. The former adsorbent was found to bind a β-galactosidase and a β-N-acetylhexosaminidase in addition to the neuraminidase, and the latter adsorbent bound the β-galactosidase in addition to the β-d-N-acetylhexosaminidase. These adsorbents effectively eliminated the contaminating glycosidase activities and a 1,500-fold purification of the neuraminidase was achieved by this procedure.The neuraminidase thus purified was homogeneous by electrophoresis on polyacrylamide gel, and its molecular weight was estimated to be 110,000 by gel filtration on Biogel P-200. The activity of the purified neuraminidase was slightly stimulated by Ca²⁺, Mg²⁺, Mn²⁺, and Co²⁺, and strongly inhibited by heavy metals. The specificity of the purified neuraminidase was almost the same with Vibrio cholerae or Clostridium perfringens neuraminidase. It completely hydrolyzes sialic acid residues in neuraminyl lactose and porcine thyroglobulin, but it liberates only 50% of sialic acid residues from porcine submaxillary mucin and ganglioside GD_1a.     

In vivo production of neuraminidase by Pasteurella multocida A:3 in goats after transthoracic challenge

Six goats were injected transthoracically with live Pasteurella multocida A:3 to examine if an extracellular enzyme, neuraminidase, was produced in vivo during infection with this organism. The principal group of goats (n = 6) each received 1 ml of live 7.5 × 10⁴ cfu of P. multocida mixed with polyacrylate beads transthoracically in the left lung on day 0 and 1 ml of live P. multocida (2.2 × 10⁸ cfu) mixed with polyacrylate beads transthoracically in the left lung on day 22. Six goats were used as negative controls and received 0.3 g of polyacrylate beads subcutaneously in the right flank on days 0 and 22. Serum was obtained from all animals on days 0, 7, 14, 22, 29, and 36. Preimmune sera from all animals showed no detectable antibody to P. multocida A:3 neuraminidase in an enzyme neutralization assay. None of the sera from the negative control animals demonstrated a significant antibody titer against the P. multocida A:3 neuraminidase. On day 36, serum samples from the six infected animals possessed complete enzyme-neutralizing activity. Anti-neuraminidase antibody could be detected as early as day 14 in the infected animals. These data show that neuraminidase is produced in vivo during an active P. multocida A:3 lobar infection. Received: 16 March 1996 / Accepted: 19 April 1996     

Extracellular neuraminidase production by Pasteurella species isolated from infected animals

A total of 721 field isolates of various Pasteurella species (haemolytica, multocida, and testudinis) from various regions of the United States were examined for extracellular neuraminidase production. All strains were grown and tested in the same way. Included were 372 P. haemolytica serotype 1 isolates, 181 P. haemolytica serotype 2 isolates, 63 P. haemolytica serotype 6 isolates, 101 Pasteurella multocida isolates, and 4 Pasteurella testudinis isolates. All Pasteurella species examined produced the enzyme. The data revealed the following: (1) Several transfers of P. haemolytica strains on blood agar medium did not cause a decrease in enzyme activity. (2) P. haemolytica serotypes 2 and 6 produce more neuraminidase than P. haemolytica serotype 1, P. multocida, and P. testudinis isolates. (3) There was no apparent change in neuraminidase production by P. haemolytica serotypes 1 and 2 obtained from the same animal taken on different days in the feedyard. (4) There was no significant change in neuraminidase production by P. haemolytica serotype 2 isolates taken from the same animal at the auction market and later at the feedyard.     

The Inhibition of Clostridium chauvoei (Jakari strain) Neuraminidase Activity by Methanolic Extracts of the Stem Barks of Tamarindus indicus and Combretum fragrans

The inhibition of neuraminidase from Clostridium chauvoei (jakari strain) with partially purified methanolic extracts of some plants used in Ethnopharmacological practice was evaluated. Extracts of two medicinal plants, Tamarindus indicus and Combretum fragrans at 100–1000 μg/ml, both significantly reduced the activity of the enzyme in a dose-dependent fashion (P < 0.001).

The estimated IC₅₀ values for Tamarindus indicus and Combretum fragrans were 100 and 150 μ/ml respectively. Initial velocity studies conducted, using fetuin as substrate revealed a non-competitive inhibition with the V_max significantly altered from 500 μmole min^?1 mg^?1 to 240μmole min^?1 mg^?1 and 340 μmole min^?1 mg^?1 in the presence of Tamarindus indicus and Combretum fragrans respectively. The K_M remained unchanged at 0.42 mM. The computed Index of physiological efficiency was reduced from 1.19 min^?1 to 0.57 min^?1 and 0.75 min^?1 with Tamarindus indicus and Combretum fragrans as inhibitors respectively.     

Inhibition of neuraminidase activity by polyphenol compounds isolated from the roots of Glycyrrhiza uralensis

We isolated 18 polyphenols with neuraminidase inhibitory activity from methanol extracts of the roots of Glycyrrhiza uralensis. These polyphenols consisted of four chalcones (1–4), nine flavonoids (5–13), four coumarins (14–17), and one phenylbenzofuran (18). When we tested the effects of these individual compounds and analogs thereof on neuraminidase activation, we found that isoliquiritigenin (1, IC₅₀ = 9.0 μM) and glycyrol (14, IC₅₀ = 3.1 μM) had strong inhibitory activity. Structure–activity analysis showed that the furan rings of the polyphenols were essential for neuraminidase inhibitory activity, and that this activity was enhanced by the apioside group on the chalcone and flavanone backbone. In addition, the presence of a five-membered ring between C-4 and C-2′ in coumestan was critical for neuraminidase inhibition. All neuraminidase inhibitors screened were found to be reversible noncompetitive inhibitors.     

A surface‐exposed neuraminidase affects complement resistance and virulence of the oral spirochaete Treponema denticola

Neuraminidases (sialidases) catalyse the removal of terminal sialic acid from glycoconjugates. Bacterial pathogens often utilize neuraminidases to scavenge host sialic acid, which can be utilized either as a nutrient or as a decorating molecule to disguise themselves from host immune attacks. Herein, a putative neuraminidase (TDE0471) was identified in Treponema denticola, an oral spirochaete associated with human periodontitis. TDE0471 is a cell surface‐exposed exo‐neuraminidase that removes sialic acid from human serum proteins; it is required for T. denticola to grow in a medium that mimics gingival crevice fluid, suggesting that the spirochaete may use sialic acid as a nutrient in vivo. TDE0471 protects T. denticola from serum killing by preventing the deposition of membrane attack complexes on the bacterial cell surface. Animal studies revealed that a TDE0471‐deficient mutant is less virulent than its parental wild‐type strain in BALB/C mice. However, it causes a level of tissue damage similar to the wild type in complement‐deficient B6.129S4‐C3^tm1Crr/J mice albeit the damage caused by both bacterial strains is more severe in these transgenic mice. Based on these results, we propose that T. denticola has evolved a strategy to scavenge host sialic acid using its neuraminidase, which allows the spirochaete to acquire nutrients and evade complement killing.     

Staining of proteoglycans in mouse lung alveoli. II. Characterization of the Cuprolinic Blue-positive, anionic sites

Summary The nature of Cuprolinic Blue-positive anionic filaments in mouse lung alveoli has been characterized. The contrast of filaments in the alveolar basement membrane of type I epithelial cells was lost on treatment with nitrous acid and pronase (without prefixation). In contrast, neither neuraminidase, chondroitinase ABC or AC, norStreptomyces hyaluronidase had any effect. Treatment with pronase (after prefixation) and 2.0m MgCl₂ (after prefixation) also had no effect, indicating that the filaments are heparan sulphate proteoglycans. The filaments in the alveolar basement membrane of type II epithelial cells and in the capillary basement membrane of the endothelial cells were also nitrous acid sensitive, but chondroitinase ABC-insensitive. A model in which the whole alveolus contains a single layer of heparan sulphate-containing proteoglycan monomers is proposed. Furthermore, the collagen fibril associated filaments remained unaffected after treatment with nitrous acid, neuraminidase orStreptomyces hyaluronidase, or after digestion with pronase (after prefixation) and treatment with 2.0m MgCl₂ (after prefixation). These filaments, however, could no longer be detected when digestion with chondroitinase ABC or pronase (without prefixation) was applied; chondroitinase AC treatment clearly affected the filaments, although they still were visible. These results indicate that the filaments are dermatan sulphate-containing proteoglycans. Some functional aspects of the proteoglycans are discussed.