Bacterial expression, characterization, and disulfide bond determination of soluble human NTPDase6 (CD39L2) nucleotidase: implications for structure and function

The ectonucleoside triphosphate diphosphohydrolases (NTPDases) control extracellular nucleotide concentrations, thereby modulating many important biological responses, including blood clotting and pain perception. NTPDases1-4 are oligomeric integral membrane proteins, whereas NTPDase5 (CD39L4) and NTPDase6 (CD39L2) are soluble monomeric enzymes, making them more amenable to thorough structural and functional analyses than the membrane-bound forms. Therefore, we report here the bacterial expression, refolding, purification, and biochemical characterization of the soluble portion of human NTPDase6. Consistent with the enzyme expressed in mammalian cells, this recombinant NTPDase6 efficiently hydrolyzes GDP, IDP, and UDP (specific activity of approximately 50000 micromol mg(-1) h(-1)), with slower hydrolysis of CDP, ITP, GTP, CTP, ADP, and UTP and virtually no hydrolysis of ATP. The K(m) for GDP (130 +/- 30 microM) is similar to that determined for the soluble rat NTPDase6 expressed in mammalian cells. The secondary structure of the refolded enzyme was determined by circular dichroism to be 33% alpha-helix, 18% beta-sheet, and 49% random coil, consistent with the secondary structure predicted from the amino acid sequence of soluble NTPDase6. Four of the five cysteine residues in the soluble NTPDase6 are highly conserved among all the NTPDases, while the fifth residue is not. Mutation of this nonconserved cysteine resulted in an enzyme very similar to wild type in its enzymology and secondary structure, indicating that this cysteine exists as a free sulfhydryl and is not essential for structure or function. The disulfide pairing of the other four cysteine residues was determined as Cys(249)-Cys(280) and Cys(340)-Cys(354) by HPLC and mass spectral analysis of tryptic peptides. Due to conservation of these cysteine residues, these two disulfide bonds are likely to exist in all NTPDases. A structural model for NTPDase6, incorporating these and other findings obtained with other NTPDases, is proposed.     

Asparagine 81, an invariant glycosylation site near apyrase conserved region 1, is essential for full enzymatic activity of ecto-nucleoside triphosphate diphosphohydrolase 3

N-linked glycosylation is important for the function, cellular localization, and oligomerization of membrane-bound ecto-nucleoside triphosphate diphosphohydrolases (eNTPDases). NTPDase3 is a prototypical cell membrane-associated eNTPDase, which is equally related and enzymatically intermediate to the other two cell surface membrane NTPDases (NTPDase1 and 2). The protein sequence of NTPDase3 contains seven putative N-glycosylation sites located in the ecto-domain. Only one of these putative glycosylation sites, asparagine 81 in NTPDase3, which is located near apyrase conserved region 1 (ACR1), is invariant in all the cell surface membrane eNTPDases. Using site-directed mutagenesis, mutants were constructed to eliminate this highly conserved N-glycosylation site in NTPDase3. The results indicate that glycosylation at this position is essential for full enzymatic activity, with mutant ATPase activity decreased more than ADPase activity. Enzymatic deglycosylation of this site is shown to be responsible for the inactivation of the wild-type enzyme by treatment with peptide N-glycosidase-F. In addition, glycosylation of this conserved site is necessary for the stabilization/stimulation of nucleotidase activity upon treatment with the lectin concanavalin A. However, lack of glycosylation at this site did not result in large changes in tertiary or quaternary structure, as measured by Cibacron blue binding, chemical cross-linking, and native gel electrophoretic analysis. Since this N-glycosylation site is invariant in cell membrane eNTPDases, it is postulated that glycosylation of this residue near ACR1 is crucial for full enzymatic activity of the cell membrane NTPDases.     

Conserved lysine 79 is important for activity of ecto-nucleoside triphosphate diphosphohydrolase 3 (NTPDase3)

Cell membrane-bound ecto-nucleoside triphosphate diphosphohydrolases (NTPDases) are homooligomeric, with native quaternary structure required for maximal enzyme activity. In this study, we mutated lysine 79 in human ecto-nucleoside triphosphate diphosphohydrolase 3 (NTPDase3). The residue corresponding to lysine 79 in NTPDase3 is conserved in all known cell surface membrane NTPDases (NTPDase1, 2, 3, and 8), but not in the soluble, monomeric NTPDases (NTPDase5 and 6), or in the intracellular, two transmembrane NTPDases (NTPDase4 and 7). This conserved lysine is located between apyrase conserved region 1 (ACR1) and an invariant glycosylation site (N81), in a region previously hypothesized to be important for NTPDase3 oligomeric structure. This lysine residue was mutated to several different amino acids, and all mutants displayed substantially decreased nucleotidase activities. A basic amino acid at this position was found to be important for the increase of nucleotidase activity observed after treatment with the lectin, concanavalin A. After solubilization with Triton X-100, mutants showed little or no decrease in activity, unlike the wild-type enzyme, suggesting that the lysine at this position may be important for maintaining proper folding and for stabilizing the quaternary structure. However, mutation at this site did not result in global changes in tertiary or quaternary structure as measured by Cibacron blue binding, chemical cross linking, and native gel electrophoretic analysis, leaving open the possibility of other mechanisms by which mutation of this conserved lysine residue might decrease enzyme activity.     

The GDA1_CD39 superfamily: NTPDases with diverse functions

The first comprehensive review of the ubiquitous “ecto-ATPases” by Plesner was published in 1995. A year later, a lymphoid cell activation antigen, CD39, that had been cloned previously, was shown to be an ecto-ATPase. A family of proteins, related to CD39 and a yeast GDPase, all containing the canonical apyrase conserved regions in their polypeptides, soon started to expand. They are now recognized as members of the GDA1_CD39 protein family. Because proteins in this family hydrolyze nucleoside triphosphates and diphosphates, a unifying nomenclature, nucleoside triphosphate diphopshohydrolases (NTPDases), was established in 2000. Membrane-bound NTPDases are either located on the cell surface or membranes of intracellular organelles. Soluble NTPDases exist in the cytosol and may be secreted. In the last 15 years, molecular cloning and functional expression have facilitated biochemical characterization of NTPDases of many organisms, culminating in the recent structural determination of the ecto-domain of a mammalian cell surface NTPDase and a bacterial NTPDase. The first goal of this review is to summarize the biochemical, mutagenesis, and structural studies of the NTPDases. Because of their ability in hydrolyzing extracellular nucleotides, the mammalian cell surface NTPDases (the ecto-NTPDases) which regulate purinergic signaling have received the most attention. Less appreciated are the functions of intracellular NTPDases and NTPDases of other organisms, e.g., bacteria, parasites, Drosophila, plants, etc. The second goal of this review is to summarize recent findings which demonstrate the involvement of the NTPDases in multiple and diverse physiological processes: pathogen-host interaction, plant growth, eukaryote cell protein and lipid glycosylation, eye development, and oncogenesis.     

Golgi-Located NTPDase1 of Leishmania major Is Required for Lipophosphoglycan Elongation and Normal Lesion Development whereas Secreted NTPDase2 Is Dispensable for Virulence

Parasitic protozoa, such as Leishmania species, are thought to express a number of surface and secreted nucleoside triphosphate diphosphohydrolases (NTPDases) which hydrolyze a broad range of nucleoside tri- and diphosphates. However, the functional significance of NTPDases in parasite virulence is poorly defined. The Leishmania major genome was found to contain two putative NTPDases, termed LmNTPDase1 and 2, with predicted NTPDase catalytic domains and either an N-terminal signal sequence and/or transmembrane domain, respectively. Expression of both proteins as C-terminal GFP fusion proteins revealed that LmNTPDase1 was exclusively targeted to the Golgi apparatus, while LmNTPDase2 was predominantly secreted. An L. major LmNTPDase1 null mutant displayed increased sensitivity to serum complement lysis and exhibited a lag in lesion development when infections in susceptible BALB/c mice were initiated with promastigotes, but not with the obligate intracellular amastigote stage. This phenotype is characteristic of L. major strains lacking lipophosphoglycan (LPG), the major surface glycoconjugate of promastigote stages. Biochemical studies showed that the L. major NTPDase1 null mutant synthesized normal levels of LPG that was structurally identical to wild type LPG, with the exception of having shorter phosphoglycan chains. These data suggest that the Golgi-localized NTPase1 is involved in regulating the normal sugar-nucleotide dependent elongation of LPG and assembly of protective surface glycocalyx. In contrast, deletion of the gene encoding LmNTPDase2 had no measurable impact on parasite virulence in BALB/c mice. These data suggest that the Leishmania major NTPDase enzymes have potentially important roles in the insect stage, but only play a transient or non-major role in pathogenesis in the mammalian host.     

Coiled‐coil interactions are required for post‐Golgi R‐SNARE trafficking

The sorting of post‐Golgi R‐SNAREs (vesicle‐associated membrane protein (VAMP)1, 2, 3, 4, 7 and 8) is still poorly understood. To address this, we developed a system to investigate their localization, trafficking and cell‐surface levels. Here, we show that the distribution and internalization of VAMPs 3 and 8 are determined solely through a new conserved mechanism that uses coiled‐coil interactions, and that VAMP4 does not require these interactions for its trafficking. We propose that VAMPs 3 and 8 are trafficked while in a complex with Q‐SNAREs. We also show that the dileucine motif of VAMP4 is required for both its internalization and retrieval to the trans‐Golgi network. However, when the dileucine motif is mutated, the construct can still be internalized potentially through coiled‐coil interactions with Q‐SNAREs.     

Crystal structure of NTPDase2 in complex with the sulfoanthraquinone inhibitor PSB-071

In many vertebrate tissues CD39-like ecto-nucleoside triphosphate diphosphohydrolases (NTPDases) act in concert with ecto-5′-nucleotidase (e5NT, CD73) to convert extracellular ATP to adenosine. Extracellular ATP is a cytotoxic, pro-inflammatory signalling molecule whereas its product adenosine constitutes a universal and potent immune suppressor. Interference with these ectonucleotidases by use of small molecule inhibitors or inhibitory antibodies appears to be an effective strategy to enhance anti-tumour immunity and suppress neoangiogenesis. Here we present the first crystal structures of an NTPDase catalytic ectodomain in complex with the Reactive Blue 2 (RB2)-derived inhibitor PSB-071. In both of the two crystal forms presented the inhibitor binds as a sandwich of two molecules at the nucleoside binding site. One of the molecules is well defined in its orientation. Specific hydrogen bonds are formed between the sulfonyl group and the nucleoside binding loop. The methylphenyl side chain functionality that improved NTPDase2-specificity is sandwiched between R245 and R394, the latter of which is exclusively found in NTPDase2. The second molecule exhibits great in-plane rotational freedom and could not be modelled in a specific orientation. In addition to this structural insight into NTPDase inhibition, the observation of the putative membrane interaction loop (MIL) in two different conformations related by a 10° rotation identifies the MIL as a dynamic section of NTPDases that is potentially involved in regulation of catalysis.     

The structure of the nucleoside triphosphate diphosphohydrolases (NTPDases) as revealed by mutagenic and computational modeling analyses

Over the last seven years our laboratory has focused on the determination of the structural aspects of nucleoside triphosphate diphosphohydrolases (NTPDases) using site-directed mutagenesis and computational comparative protein modeling to generate hypotheses and models for the hydrolytic site and enzymatic mechanism of the family of NTPDase nucleotidases. This review summarizes these studies utilizing NTPDase3 (also known as CD39L3 and HB6), an NTPDase family member that is intermediate in its characteristics between the more widely distributed and studied NTPDase1 (also known as CD39) and NTPDase2 (also known as CD39L1 and ecto-ATPase) enzymes. Relevant site-directed mutagenesis studies of other NTPDases are also discussed and compared to NTPDase3 results. It is anticipated that many of the results and conclusions reached via studies of NTPDase3 will be relevant to understanding the structure and enzymatic mechanism of all the cell-surface members of this family (NTPDase1–3, 8), and that understanding these NTPDase enzymes will aid in modulating the many varied processes under purinergic signaling control. This review also integrates the site-directed mutagenesis results with a recent 3-D structural model for the extracellular portion of NTPDases that helps explain the importance of the apyrase conserved regions (ACRs) of the NTPDases. Utilizing this model and published work from Dr Guidotti's laboratory concerning the importance and characteristics of the two transmembrane helices and their movements in response to substrate, we present a speculative cartoon model of the enzymatic mechanism of the membrane-bound NTPDases that integrates movements of the extracellular region required for catalysis with movements of the N- and C-terminal transmembrane helices that are important for control and modulation of enzyme activity.     

Cloning and characterization of mouse nucleoside triphosphate diphosphohydrolase-8

A novel mammalian plasma membrane bound nucleoside triphosphate diphosphohydrolase (NTPDase), named NTPDase8, has been cloned and characterized. Analysis of cDNA reveals an open reading frame of 1491 base pairs encoding a protein of 497 amino acid residues with an estimated molecular mass of 54650 Da and a predicted isoelectric point of 5.94. In a mouse, the genomic sequence is located on chromosome 2A3 and is comprised of 10 exons. The deduced amino acid sequence reveals eight putative N-glycosylation sites, two transmembrane domains, five apyrase-conserved regions, and 20-50% amino acid identity with other mammalian NTPDases. mRNA expression was detected in liver, jejunum, and kidney. Both intact cells and crude cell lysates from COS-7 cells expressing NTPDase8 hydrolyzed P2 receptor agonists, namely, ATP, ADP, UTP, and UDP, but did not hydrolyze AMP. There was an absolute requirement for divalent cations for the catalytic activity (Ca(2+) > Mg(2+)) with an optimal pH between 5.5 and 8.0 for ATP and 6.4 for ADP hydrolysis. Kinetic parameters derived from analysis of crude cell lysates showed that the enzyme had lower apparent K(m) values for adenine nucleotides and for triphosphonucleosides (K(m,app) of 13 microM for ATP, 41 microM for ADP, 47 microM for UTP, and 171 microM for UDP). Hydrolysis of triphosphonucleosides resulted in a transient accumulation of the corresponding diphosphonucleoside, as expected from the apparent K(m) values. Enzymatic properties of NTPDase8 differ from those of other NTPDases suggesting an alternative way to modulate nucleotide levels and consequently P2 receptor activation.     

Characterization of circulating microparticle-associated CD39 family ecto-nucleotidases in human plasma

Phosphohydrolysis of extracellular ATP and ADP is an essential step in purinergic signaling that regulates key pathophysiological processes, such as those linked to inflammation. Classically, this reaction has been known to occur in the pericellular milieu catalyzed by membrane bound cellular ecto-nucleotidases, which can be released in the form of both soluble ecto-enzymes as well as being associated with exosomes. Circulating ecto-nucleoside triphosphate diphosphohydrolase 1 (NTPDase 1/CD39) and adenylate kinase 1 (AK1) activities have been shown to be present in plasma. However, other ecto-nucleotidases have not been characterized in depth. An in vitro ADPase assay was developed to probe the ecto-enzymes responsible for the ecto-nucleotidase activity in human platelet-free plasma, in combination with various specific biochemical inhibitors. Identities of ecto-nucleotidases were further characterized by chromatography, immunoblotting, and flow cytometry of circulating exosomes. We noted that microparticle-bound E-NTPDases and soluble AK1 constitute the highest levels of ecto-nucleotidase activity in human plasma. All four cell membrane expressed E-NTPDases are also found in circulating microparticles in human plasma, inclusive of: CD39, NTPDase 2 (CD39L1), NTPDase 3 (CD39L3), and NTPDase 8. CD39 family members and other ecto-nucleotidases are found on distinct microparticle populations. A significant proportion of the microparticle-associated ecto-nucleotidase activity is sensitive to POM6, inferring the presence of NTPDases, either −2 or/and −3. We have refined ADPase assays of human plasma from healthy volunteers and have found that CD39, NTPDases 2, 3, and 8 to be associated with circulating microparticles, whereas soluble AK1 is present in human plasma. These ecto-enzymes constitute the bulk circulating ADPase activity, suggesting a broader implication of CD39 family and other ecto-enzymes in the regulation of extracellular nucleotide metabolism.     

NTPDase Specific Inhibitors Suppress Rice Infection by Magnaporthe oryzae

Evolutionarily conserved ecto‐nucleoside triphosphate diphosphohydrolases (referred to ‘NTPDases’ below) are important ecto‐nucleotidases that are able to hydrolyse NTPs and NDPs in the environment to the monophosphate form. NTPDases are found in a variety of eukaryotic organisms including medical pathogens. However, pathogenic roles of these NTPDases in medical and plant pathogens are still very obscure. Here, we demonstrate that conidial germination, appressorium formation and pathogenicity of rice blast fungus Magnaporthe oryzae that had been pretreated with NTPDase‐specific inhibitors were significantly reduced, suggesting that NTPDases of M. oryzae play an important role in its infection. Our findings may provide a new avenue for powerful fungicide development and the control of rice blast.     

Comparative hydrolysis of P2 receptor agonists by NTPDases 1, 2, 3 and 8

Nucleoside triphosphate diphosphohydrolases 1, 2, 3 and 8 (NTPDases 1, 2, 3 and 8) are the dominant ectonucleotidases and thereby expected to play important roles in nucleotide signaling. Distinct biochemical characteristics of individual NTPDases should allow them to regulate P2 receptor activation differentially. Therefore, the biochemical and kinetic properties of these enzymes were compared. NTPDases 1, 2, 3 and 8 efficiently hydrolyzed ATP and UTP with K_m values in the micromolar range, indicating that they should terminate the effects exerted by these nucleotide agonists at P2X_1–7 and P2Y_2,4,11 receptors. Since NTPDase1 does not allow accumulation of ADP, it should terminate the activation of P2Y_1,12,13 receptors far more efficiently than the other NTPDases. In contrast, NTPDases 2, 3 and 8 are expected to promote the activation of ADP specific receptors, because in the presence of ATP they produce a sustained (NTPDase2) or transient (NTPDases 3 and 8) accumulation of ADP. Interestingly, all plasma membrane NTPDases dephosphorylate UTP with a significant accumulation of UDP, favoring P2Y₆ receptor activation. NTPDases differ in divalent cation and pH dependence, although all are active in the pH range of 7.0–8.5. Various NTPDases may also distinctly affect formation of extracellular adenosine and therefore adenosine receptor-mediated responses, since they generate different amounts of the substrate (AMP) and inhibitor (ADP) of ecto-5-nucleotidase, the rate limiting enzyme in the production of adenosine. Taken together, these data indicate that plasma membrane NTPDases hydrolyze nucleotides in a distinctive manner and may therefore differentially regulate P2 and adenosine receptor signaling.     

Trafficking and intracellular ATPase activity of human ecto-nucleotidase NTPDase3 and the effect of ER-targeted NTPDase3 on protein folding

Ecto-nucleoside triphosphate diphosphohydrolases, NTPDase1 (CD39) and NTPDase3, are integral plasma membrane proteins that hydrolyze extracellular nucleotides, thereby modulating the function of purinergic receptors. During processing in the secretory pathway, the active sites of ecto-nucleotidases are located in the lumen of vesicular compartments, thus raising the question whether the ecto-nucleotidases affect the ATP-dependent processes in these compartments, including protein folding in the endoplasmic reticulum (ER). It has been reported (J. Biol. Chem. (2001) 276, 41518-41525) that CD39 is not active until it reaches the plasma membrane, suggesting that terminal glycosylation in Golgi is critical for its activity. To investigate the subcellular location and the mechanism of ecto-nucleotidase activation, we expressed human NTPDase3 in COS-1 cells and blocked the secretory transport with monensin or brefeldin A, or by targeting to ER with a signal peptide. Cell surface biotinylation, sensitivity to glycosidases, and fluorescence microscopy analyses suggest that, in contrast to the previous report on CD39, NTPDase3 becomes catalytically active in the ER or in the ER-Golgi intermediate compartment, and that terminal glycosylation in Golgi is not essential for activity. Moreover, ER-targeted NTPDase3, but not wild-type NTPDase3 or ER-targeted inactive G221A mutant, significantly diminished the folding efficiency and the transport to the plasma membrane of coexpressed CD39 used as a reporter protein. These data suggest that ER-targeted NTPDase3 significantly depletes ATP in ER, whereas wild-type NTPDase3 is likely to acquire ATPase activity in a post-ER, but pre-Golgi, compartment, thus avoiding unproductive ATP hydrolysis and interference with protein folding in the ER. ER-targeted NTPDase3 may be a useful experimental tool to study the effects of ER ATP depletion on ER function under normal and stress conditions.     

The role of the NTPDase enzyme family in parasites: what do we know, and where to from here?

Nucleoside triphosphate diphosphohydrolases (NTPDases, GDA1_CD39 protein superfamily) play a diverse range of roles in a number of eukaryotic organisms. In humans NTPDases function in regulating the inflammatory and immune responses, control of vascular haemostasis and purine salvage. In yeast NTPDases are thought to function primarily in the Golgi, crucially involved in nucleotide sugar transport into the Golgi apparatus and subsequent protein glycosylation. Although rare in bacteria, in Legionella pneumophila secreted NTPDases function as virulence factors. In the last 2 decades it has become clear that a large number of parasites encode putative NTPDases, and the functions of a number of these have been investigated. In this review, the available evidence for NTPDases in parasites and the role of these NTPDases is summarized and discussed. Furthermore, the processes by which NTPDases could function in pathogenesis, purine salvage, thromboregulation, inflammation and glycoconjugate formation are considered, and the data supporting such putative roles reviewed. Potential future research directions to further clarify the role and importance of NTPDases in parasites are proposed. An attempt is also made to clarify the nomenclature used in the parasite field for the GDA1_CD39 protein superfamily, and a uniform system suggested.     

Characterization of disulfide bonds in human nucleoside triphosphate diphosphohydrolase 3 (NTPDase3): implications for NTPDase structural modeling

Cell-surface nucleotidases (NTPDases) contain 10 invariant cysteine residues in their extracellular regions. To investigate disulfide structure in human NTPDase3, we made single and double mutants of these 10 cysteines, and analyzed their enzymatic activity, glycosylation pattern, trafficking to the cell membrane, and sensitivity to reduction. The mutants constituted five distinct phenotypes, thus, strongly suggesting disulfide bonds between C92-C116 (first bond), C261-C308 (second bond), C289-C334 (third bond), C347-C353 (fourth bond), and C399-C422 (fifth bond). Due to conservation of the 10 cysteines, the identified five disulfide bonds are likely to exist in all cell-surface NTPDases. The third and fifth bonds are also present in the soluble NTPDases and are critical for processing, trafficking, and enzymatic activity. The fourth bond has minimal effect on processing and function, while the first and second bonds are of intermediate importance. Most of the N-linked glycosylation sites in the wild-type enzyme are processed to complex oligosaccharides, but at least one site is high-mannose or hybrid in structure. Interestingly, disruption of the first disulfide bond resulted in some enzyme that lost sensitivity to endoglycosidase H, suggesting that the first disulfide bond in the wild-type enzyme shields some high-mannose glycans from terminal glycosylation. Comparative modeling by threading and homology modeling of the NTPDase3 sequence revealed a high degree of structural fold similarity with a bacterial exopolyphosphatase (PDB ). The resultant theoretical 3-D model of the extracellular portion of NTPDase3, based on homology with this exopolyphosphatase, is consistent with the assignment of the disulfide bonds occurring in regions of good fold similarity between NTPDase3 and the exopolyphosphatase. The 3-D model obtained for NTPDase3 also suggests the structural basis for the importance of several apyrase conserved regions for the nucleotidase activities of the NTPDases.     

Cloning and characterization of the ecto-nucleotidase NTPDase3 from rat brain: Predicted secondary structure and relation to other members of the E-NTPDase family and actin

The protein family of ecto-nucleoside triphosphate diphosphohydrolases (E-NTPDase family) contains multiple members that hydrolyze nucleoside 5'-triphosphates and nucleoside 5'-diphosphates with varying preference for the individual type of nucleotide. We report the cloning and functional expression of rat NTPDase3. The rat brain-derived cDNA has an open reading frame of 1590 bp encoding 529 amino acid residues, a calculated molecular mass of 59.1 kDa and predicted N- and C-terminal hydrophobic sequences. It shares 94.3% and 81.7% amino acid identity with the mouse and human NTPDase3, respectively, and is more closely related to cell surface-located than to the intracellularly located members of the enzyme family. The NTPDase3 gene is allocated to chromosome 8q32 and organized into 11 exons. Rat NTPDase3 expressed in CHO cells hydrolyzed both nucleoside triphosphates and nucleoside diphosphates with hydrolysis ratios of ATP:ADP of 5:1 and UTP:UDP of 8:1. After addition of ATP, ADP is formed as an intermediate product that is further hydrolyzed to AMP. The enzyme is preferentially activated by Ca(2+) over Mg(2+) and reveals an alkaline pH optimum. Immunocytochemistry confirmed expression of heterologously expressed NTPDase3 to the surface of CHO cells. PC12 cells express endogenous surface-located NTPDase3. An immunoblot analysis detects NTPDase3 in all rat brain regions investigated. An alignment of the secondary structure domains of actin conserved within the actin/HSP70/sugar kinase superfamily to those of all members of the NTPDase family reveals apparent similarity. It infers that NTPDases share the two-domain structure with members of this enzyme superfamily.     

High expression and activity of ecto-5′-nucleotidase/CD73 in the male murine reproductive tract

Extracellular ATP and its hydrolysis product adenosine modulate various reproductive functions such as those requiring contraction, steroidogenesis, and maintenance of fluid composition. Interestingly, adenosine might act as a key capacitative effector for mammalian spermatozoa to acquire the capacity for fertilisation. Extracellular nucleotide levels are affected by cell surface ectonucleotidases, amongst which the ectonucleoside triphosphate diphosphohydrolase (E-NTPDase) family regroups the most abundant and effective enzymes to hydrolyse ATP and ADP to AMP in physiological conditions. In the male reproductive tract three members of this family have been indentified: NTPDase1, NTPDase2 and NTPDase3 (Martín-Satué et al. in Histochem Cell Biol 131:615–628, 2009). The purpose of the present study was to characterize in the male reproductive tract the expression profile of the main enzyme responsible for the generation of adenosine from AMP, namely the ecto-5′-nucleotidase (CD73). The enzyme was identified by immunological techniques and by in situ enzymatic assays, including inhibition experiments with α,β-methylene-ADP, a specific CD73 inhibitor. High levels of ecto-5′-nucleotidase were detected in testes in association with both germinal and somatic cells, in smooth muscle cells throughout the tract, in secretory epithelia from exocrine glands, and remarkably, in principal cells of epididymis, where co-localization with NTPDase3 was found. The relevance of this co-expression on nucleotide hydrolysis in these cells directly involved in the control of sperm fluid composition was addressed biochemically. This study suggests close regulation of extracellular nucleoside and nucleotide levels in the genital tract by ecto-5′-nucleotidase that, in concurrence with NTPDases, may impact male fertility.     

Crystallographic evidence for a domain motion in rat nucleoside triphosphate diphosphohydrolase (NTPDase) 1

Nucleoside triphosphate diphosphohydrolases (NTPDases) are a physiologically important class of membrane-bound ectonucleotidases responsible for the regulation of extracellular levels of nucleotides. CD39 or NTPDase1 is the dominant NTPDase of the vasculature. By hydrolyzing proinflammatory ATP and platelet-activating ADP to AMP, it blocks platelet aggregation and supports blood flow. Thus, great interest exists in understanding the structure and dynamics of this prototype member of the eukaryotic NTPDase family. Here, we report the crystal structure of a variant of soluble NTPDase1 lacking a putative membrane interaction loop identified between the two lobes of the catalytic domain. ATPase and ADPase activities of this variant are determined via a newly established kinetic isothermal titration calorimetry assay and compared to that of the soluble NTPDase1 variant characterized previously. Complex structures with decavanadate and heptamolybdate show that both polyoxometallates bind electrostatically to a loop that is involved in binding of the nucleobase. In addition, a comparison of the domain orientations of the four independent proteins in the crystal asymmetric unit provides the first direct experimental evidence for a domain motion of NTPDases. An interdomain rotation angle of up to 7.4° affects the active site cleft between the two lobes of the protein. Comparison with a previously solved bacterial NTPDase structure indicates that the domains may undergo relative rotational movements of more than 20°. Our data support the idea that the influence of transmembrane helix dynamics on activity is achieved by coupling to a domain motion.     

Polyoxometalates--a new class of potent ecto-nucleoside triphosphate diphosphohydrolase (NTPDase) inhibitors

Polyoxotungstates were identified as potent inhibitors of NTPDases1, 2, and 3. The most potent compound was K(6)H(2)[TiW(11)CoO(40)], exhibiting K(i) values of 0.140 microM (NTPDase1), 0.910 microM (NTPDase2), and 0.563 microM (NTPDase3). One of the compounds, (NH(4))(18)[NaSb(9)W(21)O(86)], was selective for NTPDases2 and 3 versus NTPDase1. NTPDase inhibition might contribute to the described biological effects of polyoxometalates, including their anti-cancer activity.