Triatoma infestans apyrases belong to the 5'-nucleotidase family

Apyrases are nucleoside triphosphate-diphosphohydrolases (EC 3.6.1.5) present in a variety of organisms. The apyrase activity found in the saliva of hematophagous insects is correlated with the prevention of ADP-induced platelet aggregation of the host during blood sucking. Purification of apyrase activity from the saliva of the triatomine bug Triatoma infestans was achieved by affinity chromatography on oligo(dT)-cellulose and gel filtration chromatography. The isolated fraction includes five N-glycosylated polypeptides of 88, 82, 79, 68 and 67 kDa apparent molecular masses. The isolated apyrase mixture completely inhibited aggregation of human blood platelets. Labeling with the ATP substrate analogue 5'-p-fluorosulfonylbenzoyladenosine showed that the five species have ATP-binding characteristic of functional apyrases. Furthermore, tandem mass spectroscopy peptide sequencing showed that the five species share sequence similarities with the apyrase from Aedes aegypti and with 5'-nucleotidases from other species. The complete cDNA of the 79-kDa enzyme was cloned, and its sequence confirmed that it encodes for an apyrase belonging to the 5'-nucleotidase family. The gene multiplication leading to the unusual salivary apyrase diversity in T. infestans could represent an important mechanism amplifying the enzyme expression during the insect evolution to hematophagy, in addition to an escape from the host immune response, thus enhancing acquisition of a meal by this triatomine vector of Chagas' disease.     

Kinetics of expression of the salivary apyrases in Triatoma infestans

Apyrases are nucleoside triphosphate-diphosphohydrolases that remove Pi from ATP and ADP. The blood feeding reduviid Triatoma infestans, which transmits the Trypanosoma cruzi agent of Chagas disease to animals and man, presents in its salivary glands five apyrases with molecular masses of 88, 82, 79, 68 and 67 kDa. These triatomine apyrases have been associated with the prevention of ADP induced platelet aggregation in the host. Here we provide biochemical data showing that these apyrases are stored in the lumen of the salivary gland D1 pairs, and that about one half of the pool of the enzyme is consumed during feeding. After the feeding recovery of apyrases to maximal activity level takes days, thus suggesting de novo protein synthesis. This hypothesis is supported by quantitative RT-PCR analysis which shows an upregulation of the 79 kDa apyrase mRNA level after feeding.     

ATP hydrolyzing salivary enzymes of caterpillars suppress plant defenses

The oral secretions of herbivores are important recognition cues that can be used by plants to mediate induced defenses. In this study, a degradation of adenosine-5'-triphosphate (ATP) in tomato leaves was detected after treatment with Helicoverpa zea saliva. Correspondingly, a high level of ATPase activity in saliva was detected and three ATP hydrolyzing enzymes: apyrase, ATP synthase and ATPase 13A1 were identified in salivary glands. To determine the functions of these proteins in mediating defenses, they were cloned from H. zea and expressed in Escherichia coli. By applying the purified expressed apyrase, ATP synthase or ATPase 13A1 to wounded tomato leaves, it was determined that these ATP hydrolyzing enzymes suppressed the defensive genes regulated by the jasmonic acid and ethylene pathways in tomato plant. Suppression of glandular trichome production was also observed after treatment. Blood-feeding arthropods employ 5'-nucleotidase family of apyrases to circumvent host responses and the H. zea apyrase, is also a member of this family. The comparatively high degree of sequence similarity of the H. zea salivary apyrase with mosquito apyrases suggests a broader evolutionary role for salivary apyrases than previously envisioned.     

New protein inhibitors of cysteine proteinases in human saliva and salivary glands

New protein inhibitors of cysteine proteinases were found in human saliva and salivary glands. The inhibitory potency present in saliva against ficin is about 30% of that in serum: 1 ml of saliva gives 100% inhibition of 1 nmol of ficin. The same amount of saliva causes no inhibition of 1 nmol of trypsin. The salivary inhibitors occur as multiple forms with different isoelectric points (pI of 4.5-4.7, 5.8, 6.8, 7.8 and 8.2) and different molecular masses of approximately 16, 11, 10, 9.5 and 9 kDa. The inhibitor forms having molecular masses of less than 11 kDa have not yet been described by other authors. The salivary inhibitors have a high thermal stability and a high stability both in alkaline and acidic solutions.     

Purification and comparison of the structures of human liver acidic alpha-D-mannosidases A and B.

Human liver alpha-D-mannosidases A and B were purified 11 500-fold and 2000-fold respectively. Both showed microheterogeneity when analysed by isoelectric focusing. Alpha-D-Mannosidases A and B are immunologically identical but differ in their range of pI values, molecular masses, uptake into fibroblasts and subunit compositions. Alpha-D-Mannosidase A consists of equimolar proportions of subunits of molecular masses 62 kDa and 26 kDa, which are linked by disulphide bridges in the intact enzyme. Alpha-D-Mannosidase B also contains a small subunit, of molecular mass 26 kDa, and a variable mixture of larger subunits, of molecular masses 58 kDa and 62 kDa. The 62 kDa and 58 kDa subunits, but not the 26 kDa one, contain concanavalin A-recognizing glycans. The 58 kDa subunit has a lower pI, contains less high-mannose glycans but probably contains more mannose 6-phosphate than the 62 kDa subunit. It is postulated that the differences in structure and properties of alpha-D-mannosidases A and B are due to differences in the state of processing of the large subunit. This suggestion is consistent with a single locus on chromosome 19 for lysosomal alpha-D-mannosidase.     

Changes in isotypes and enzyme activity of apyrase during germination of dark-grown pea (Pisum sativum) seedlings

In the present study we used 2D-PAGE and Western blotting to investigate the expression of different isotypes of apyrase (EC 3.6.1.5) during imbibition, germination and initial growth of pea ( Pisum sativum L . var. Alaska) seedlings in the dark. The 49 kDa apyrase was absent in the 10-h imbibed embryos, but began to appear after 16 h germination and increased with germination time. By 62 h, there were five isotypes present at pI 5.8, 6.0, 6.3, 6.6 and 6.8, with those at pI 6.0, 6.3, and 6.6 being most abundant and the one at pI 6.3 predominating, whereas the most acidic and basic isotypes were only present in significant amounts in seedlings after 62 h germination. Stems contained all five isotypes and had more pI 6.0, 6.3 and 6.6 isotype than the plumules, whereas in the roots there were very small amounts of all isotypes. Partial amino acid sequencing showed that all isotypes were identical with apy1, not the more recently described apy2. Apyrase activity was absent in imbibed embryos, but increased sharply during germination and reached a maximum after 62 h. Based upon the capability of the enzyme to hydrolyse ATP, CTP, GTP, TTP, UTP, and ADP (but not AMP), its susceptibility to various ATPase inhibitors, and coincidence of expression of the protein and enzyme activity, we estimate that 50–70% of the ATPase activity results from the 49 kDa apyrase. The present results suggest that isotypes of pI 6.0, 6.3, and 6.6 are physiologically important and strongly indicate a crucial role for apyrase in the differentiation and development of pea seedlings.     

Modeling studies of potato nucleoside triphosphate diphosphohydrolase NTPDase1: an insight into the catalytic mechanism

Nucleoside triphosphate diphosphohydrolase--NTPDase1 (apyrase, EC 3.6.1.5) was modeled based on sequence homology. The single polypeptide chain of apyrase is folded into two domains. The putative catalytic site with the apyrase conserved regions (ACR 1-5) is located between these two domains. Modeling confirmed that apyrase belongs to the actin superfamily of proteins. The amino acids interacting with the nucleoside triphosphate substrate and probably involved in the catalyzed hydrolysis were identified. The proposed two-step catalytic mechanism of hydrolysis involves Thr127 and Thr55 as potential nucleophilic factors responsible for the cleavage of the Pgamma and Pbeta anhydride bonds, respectively. Their action seems to be assisted by Glu170 and Glu78 residues, respectively. The presence of two nucleophiles in the active site of apyrase explains the differences in the hydrolytic activity between apyrases and other enzymes belonging to the NTPDase family.     

Differential regulation of a family of apyrase genes from Medicago truncatula

Four putative apyrase genes were identified from the model legume Medicago truncatula. Two of the genes identified from M. truncatula (Mtapy1 and Mtapy4) are expressed in roots and are inducible within 3 h after inoculation with Sinorhizobium meliloti. The level of mRNA expression of the other two putative apyrases, Mtapy2 and Mtapy3, was unaffected by rhizobial inoculation. Screening of a bacterial artificial chromosome library of M. truncatula genomic DNA showed that Mtapy1, Mtapy3, and Mtapy4 are present on a single bacterial artificial chromosome clone. This apyrase cluster was mapped to linkage group seven. A syntenic region on soybean linkage group J was found to contain at least two apyrase genes. Screening of nodulation deficient mutants of M. truncatula revealed that two such mutants do not express apyrases to any detectable level. The data suggest a role for apyrases early in the nodulation response before the involvement of root cortical cell division leading to the nodule structure.     

Comparative subcellular distribution of apyrase from animal and plant sources. Characterization of microsomal apyrase

1. Apyrase (ATP: diphosphohydrolase) has been found in the microsomal fraction of rat salivary gland, mammary gland and uterus. 2. This enzyme, already described in plant tissue, is mainly present as a soluble polypeptide in tubers of Solanum tuberosum. 3. A fraction of this enzyme is associated with the microsomal fraction with a higher specific activity than the soluble one, for either ATP or ADP as substrate. 4. Apyrase bound to microsomes from rat and potato tissues was characterized in its substrate specificity and effect of inhibitors. 5. The Km values for ATP and ADP, optimum pH and metal ion requirement were determined. 6. A characteristic common to the microsomal and soluble apyrases is the stimulatory effect of a potato activator protein of soluble plant apyrase. 7. The microsomal-bound apyrase from rat and potato tissues were solubilized and subjected to size-exclusion chromatography. 8. The mammary gland and salivary gland apyrases eluted as molecular aggregates, in contrast to the uterus and potato enzyme.     

Disruption of apyrases inhibits pollen germination in Arabidopsis

In Arabidopsis, we previously identified two highly similar apyrases, AtAPY1 and AtAPY2. Here, T-DNA knockout (KO) mutations of each gene were isolated in a reverse genetic approach. The single KO mutants lacked a discernible phenotype. The double KO mutants, however, exhibited a complete inhibition of pollen germination, and this correlated with positive beta-glucuronidase staining in the pollen of apyrase promoter:beta-glucuronidase fusion transgenic lines. The vast majority of the pollen grains of these mutants were identical to wild type in size, shape, and nuclear state and were viable as assayed by metabolic activity and plasma membrane integrity. Complementation with either AtAPY1 or AtAPY2 cDNA rescued pollen germination, confirming that the phenotype was apyrase specific. Despite the redundancy of the two apyrases in rescue potential, transmission analyses suggested a greater role for AtAPY2 in male gamete success. The effect of mutant apyrase on the transmission through the female gametophyte was only marginal, and embryo development appeared normal in the absence of apyrases. The male-specific double KO mutation is fully penetrant and shows that apyrases play a crucial role in pollen germination.     

Proteolytic processing of human lysosomal arylsulfatase A.

Arylsulfatase A purified from human placenta contained an unreported component with an apparent molecular mass of 7 kDa in addition to the two known components with apparent molecular masses of 58 and 50 kDa. The detailed relationship between the 58 kDa component and the 50 kDa component is as yet unknown. The present study was undertaken to define the structure of the subunits of the sulfatase. The N-terminal sequence of the 50 kDa component was identical to that of the 58 kDa component. Furthermore, the peptide maps of the 50 kDa component, which was separately digested with trypsin and Achromobacter proteinase I, were quite similar to those of the 58 kDa one. Through sequence analysis of the incompatible peaks in the peptide maps, the 50 kDa component was found to lack a sequence from Val-445 to the C-terminus. On the other hand, the N-terminal sequence of the 7 kDa component began with Ala-448, though there was a minor sequence commencing with Thr-449. These observations suggest that the 50 and 7 kDa components were produced by limited proteolysis near the C-terminus of the 58 kDa component. Through analysis using unreducing SDS-PAGE, the 58 and the 7 kDa components were found to be linked by disulphide bonds. Arylsulfatase A purified from human liver was also composed of the same subunits as the placental one. This finding suggests that human arylsulfatase A undergoes similar proteolytic processing regardless of the tissue involved.     

Apyrase Activity and Platelet Aggregation Inhibitors in the Tick Ornithodoros Savignyi (Acari: Argasidae)

Ticks are ectoparasites that cause considerable damage to their hosts while feeding. The feeding process is facilitated by anti-haemostatic factors present in the tick saliva. Apyrase (ATP diphosphohydrolase, EC 3.6.1.5) is a platelet aggregation inhibitor found in most haematophagous organisms studied. The present study describes the identification and characterization of such an activity in the tick Ornithodoros savignyi. The enzyme conformed to many properties common to apyrases. These included a low substrate specificity, dependence on bivalent metal ions for activity and insensitivity to the classical ATPase inhibitors. Heat denaturation studies, pH optima and similar effects of inhibitors on the enzyme's ATP and ADP hydrolysing activities supported its classification as an apyrase. Salivary gland extracts inhibited the platelet aggregation induced by ADP, collagen and thrombin and disaggregated aggregated platelets. The results suggest the presence of two or more anti-platelet factors present in the salivary glands of this tick species.     

Labelling and immunoprecipitation of thyroid microsomal antigen

Human thyroid microsomes have been solubilized, labelled with ¹²⁵I, immunoprecipitated with microsomal antibody and analysed by gel electrophoresis. The analysis indicated that two peptides of relative molecular masses 108 and 118 kDa, under reducing conditions, were specifically immunoprecipitated by microsomal antibody. Similar values were obtained under non-reducing conditions indicating that the two peptides were not linked by disulphide bridges to each other or to different peptides. These results suggest that the microsomal antigen contains two components which may be linked by non-covalent bonds to form a single protein of 230 kDa. Studies with lectin affinity columns suggested that the antigen was glycosylated.     

Characterization of a 22 kDa protein with widespread tissue distribution but which is uniquely present in secretions of the testis and epididymis and on the surface of spermatozoa

The purification is reported of a 22 kDa protein which was first identified as one of the major components of the luminal secretion of the rat testis and epididymis. Antibodies against the 22 kDa protein cross-reacted with a protein of the same molecular weight in cytosolic extracts of other tissues from both male and female rats. However, since the protein could not be detected in blood, peritoneal fluid, saliva, milk, uterine fluid, seminal vesicle secretion, coagulating gland secretion or prostatic secretion, it would appear that the testis and epididymis may be unique in containing the protein in a soluble form within their luminal secretions. Proteins with slightly lower molecular weight were detected by the antibodies in cytosolic extracts of tissues from other animals (mice, rabbits, sheep, pigs, cattle), indicating that the protein may be conserved in a variety of species. However, in contrast to the rat, the protein was apparently not present in the testicular and epididymal secretions of these species. In addition to the occurrence of the 22 kDa protein as a soluble moiety in rat testicular and epididymal fluids, the protein was also located on sperm plasma membranes where its distribution was restricted to the surface of the flagellum. Amongst sperm surface proteins, the 22 kDa protein was the major protein containing sulphydryl groups and one of the major entities containing disulphide bonds. These properties may be of importance in the maintenance of sperm viability.     

Protein structural changes associated with active and inactive states of hydrogenase from Thiocapsa roseopersicina

Electrophoretic and isoelectrofocusing behavior of the hydrogenase from Thiocapsa roseopersicina under various conditions revealed remarkable properties of this enzyme: there are two active forms which differ in their molecular masses as well as in oxygen sensitivity; the apparent molecular masses of the active hydrogenase forms (90 and 49 kDa) differ considerably from those in the inactive state (64, 34, and 15 kDa); the active forms and some of the inactivated ones can be transformed into each other reversibly; urea can unfold the 64 and 34 kDa proteins but not the 49 kDa form at room temperature; the pI of these proteins are different in the presence of urea. The results suggest large rearrangements in the hydrogenase protein structure which are associated with the enzymatically active and inactive states. It is concluded that reversible formation of disulfide bonds cannot be the major cause for maintaining the enzyme conformation. Strong hydrophobic interactions are suggested to be primarily responsible for the structural stability and for the rearrangements.     

Purification and characterisation of phenoloxidase from amphioxus Branchiostoma belcheri tsingtauense

Phenoloxidase (PO) from the humoral fluid of amphioxus B. belcheri tsingtauense was purified using a sequential combination of ammonium sulphate precipitation, Sephadex G-200 chromatography and DEAE Sepharose Fast Flow chromatography. In PAGE, the purified enzyme exhibited a single band of 150 kDa under non-reducing conditions, and was resolved to three bands with molecular masses of 72, 46 and 44 kDa, respectively, under reducing conditions, suggesting that the PO in amphioxus humoral fluid seems to be a heterotrimer of three polypeptides held together by disulphide bonds. The substrate specificity and inhibition characteristics both indicate that the PO isolated from amphioxus humoral fluid is a tyrosinase-type enzyme. In addition, mouse antisera against the purified PO were prepared, and their specificity was confirmed by Western blotting, facilitating the future determination of the origin of PO in the humoral fluid and the distribution of PO-synthesising tissues in amphioxus.     

Protein pattern of exhaled breath condensate and saliva

The proteins recovered in exhaled breath condensate (EBC) might be used to non-invasively monitor respiratory diseases. However, the range of proteins and their source are still unresolved and contamination by saliva or a similar protein pattern in the nasal and bronchial compartments may make interpretation of the data difficult. We studied nasal EBC (collected through a "free of touch" technique by negative pressure), oral tidal, and oral forced EBC (collected through a rebreathing valve as a saliva trap connected to tubing submerged into ice) and matched saliva samples from five healthy adult subjects. The protein samples were separated by two-dimensional electrophoresis and the silver stained gels were analyzed by Melanie 2 software. In both nasal and oral EBC, three spots (72 kDa/isoelectric point (pI) 6.6-7.0, 66 kDa/pI 5.9-6.7 and 45-48 kDa/pI 8.0-8.6) were consistently present in all subjects. Several other proteins were only sporadically detected. Despite improbable saliva contamination (no phosphorus contamination in the same oral and nasal EBC, no amylase activity in 10 pairs of nasal and oral EBC collected by the same technique), on average 63% and 71% of the spots identified in oral and nasal EBC were also found in the matched individual saliva samples. Compared to saliva, the range and amount of protein in all types of EBC was very small. Even when collected free of saliva contamination the majority of proteins present in EBC was also found in saliva, suggesting that these proteins are present in both compartments, e.g. saliva and secretions of the lower airspaces. The quantification and identification of specific proteins in the various compartments is warranted in future studies to determine the practical value of EBC.     

Structural studies of two apyrases from Solanum tuberosum

The proportion of acid and basic amino acid residues obtained for two homogeneous isoenzymes of apyrase isolated from different clonal varieties of Solanum tuberosum (Pimpernel and Desirée) was essentially the same. This does not agree with the difference in pI values observed. Treatment with asparaginase and glutaminase caused partial inactivation of both enzyme activities in both isoenzymes, and pI values were changed, but not equalized. The differences in pI values of the native isoenzymes may still be attributed to different proportions of glutamine and asparagine in the primary structure. Leucine is the amino-terminal residue in both isoenzymes. Both have two disulphide bridges and one buried sulphydryl group which is not essential for enzyme activity. Differences in pI values should thus be attributed to factors other than amino acid composition.     

A Nod factor-binding lectin is a member of a distinct class of apyrases that may be unique to the legumes

Recent studies from our laboratory have found that a root lectin from the legume Dolichos biflorus is present on the root surface, binds rhizobial Nod factor and has apyrase activity. To assess the broader significance of this lectin/nucleotide phosphohydrolase (Db-LNP), we have cloned a second related cDNA (Db-apyrase-2) from D. biflorus, as well as related cDNAs from the legumes Lotus japonicus and Medicago sativa, and from Arabidopsis thaliana, a non-legume. The deduced amino acid sequences of these apyrases were aligned with one another and with the sequences of other apyrases from plants, animals, yeast and protozoa. Phylogenetic analysis shows that Db-LNP has closely related orthologs only in other legumes, while Db-apyrase-2 is more closely related to apyrase sequences from non-leguminous plants. We also show that the orthologs of Db-LNP from M. sativa and Pisum sativum have carbohydrate binding activity. The results suggest that legume LNPs may represent a special class of apyrases that arose by gene duplication and subsequent specialization. Received: 11 March 1999 / Accepted: 14 June 1999