Novel partial reduction of the humanized anti-cocaine mAb h2E2 for selective cysteine labeling.

Monoclonal antibodies are utilized for treating many diseases and disorders, as well as for basic research and development. Covalent labeling of mAbs is important for various antibody applications and creating antibody drug conjugates. Labeling at reactive lysine residues using lysine selective reagents is useful, but is non-selective and can interfere with antigen binding and interactions of the Fc antibody region. In this work, using an anti-cocaine mAb (h2E2), we utilized triphenylphosphine-3,3',3″-trisulfonic acid (TPPTS), and demonstrated for the first time reduction of disulfides in an antibody by TPPTS. More importantly, this reduction was very reproducible, limited, and selective, and permitted selective labeling of the antibody with a cysteine reactive fluorescent reagent, resulting in labeling of a few specific cysteines. Similar results were obtained using TCEP-agarose reduction. We demonstrated that both of these selective partial reduction methods gave rise to approximately two labels per mAb, mostly by selective reduction of the heavy chain to light chain disulfide bond, as demonstrated by non-reducing SDS-PAGE protein band analysis. Thus, convenient, reproducible, and selective mAb disulfide reduction was achieved under mild conditions. These labeled, partially reduced mAbs were characterized by differential scanning fluorimetry (DSF), detecting the incorporated fluorescein instead of an exogenously added dye, and for antigen (cocaine) binding by isothermal titration calorimetry (ITC). Both the structure and antigen binding of the mAb was maintained. This novel selective reduction and labeling is generally relevant to modification of antibodies and to future development of conjugated mAbs for experimental and therapeutic purposes.

Multi-domain unfolding of the Fab fragment of a humanized anti-cocaine mAb characterized by non-reducing SDS-PAGE.

Monoclonal antibodies and their fragments are widely used for research and therapy. Fab fragments are useful since they retain antigen binding specificity, but being smaller proteins, are better able to penetrate biological compartments and tumors, and do not induce Fc-dependent immunological system activation. Our laboratory developed an anti-cocaine mAb (named h2E2) for the treatment of cocaine use disorders, which is currently in advanced pre-clinical development. We are also interested in the Fab fragment of this mAb for potential therapy of acute cocaine overdose. Previously, we showed that this mAb and its F(ab')2 and Fab fragments undergo discrete domain unfolding, as detected by non-reducing SDS-PAGE, and that ligand-induced protein thermal stabilization can be quantitated utilizing differential scanning fluorimetry in the absence of SDS. Here, we demonstrate that multiple Fab protein gel bands observed using non-reducing SDS-PAGE in the presence and absence of cocaine and its metabolites can be explained and interpreted based on the differential stabilization of two unfolding domains in the Fab fragment. The variable domain is stabilized by ligands against SDS unfolding, while the constant domain is not. This data and its interpretation are also supported by differential scanning fluorimetry data for the Fab fragment in SDS. It is likely that these non-reducing SDS-PAGE results and the gel band domain unfolding model will be applicable to other small molecule binding antibodies. Thus, non-reducing SDS-PAGE is a widely available and simple method for assessing domain stability and multi-step unfolding of Fab fragments.

Selective disulfide reduction for labeling and enhancement of Fab antibody fragments.

Many methods have been developed for chemical labeling and enhancement of the properties of antibodies and their common fragments, including the Fab and F(ab')2 fragments. Somewhat selective reduction of some antibody disulfide bonds has been previously achieved, yielding antibodies and antibody fragments that can be labeled at defined sites, enhancing their utility and properties. Selective reduction of the two hinge disulfide bonds present in F(ab')2 fragments using mild reduction has been useful. However, such reduction is often not quantitative and results in the reduction of multiple disulfide bonds, and therefore subsequent multiple labeling or conjugation sites are neither homogenous nor stoichiometric. Here, a simple and efficient selective reduction of the single disulfide bond linking the partial heavy chain and the intact light chain which compose the Fab fragment is accomplished utilizing tris(2-carboxyethyl)phosphine (TCEP) immobilized on agarose beads. The resultant reduced cysteine residues were labeled with several cysteine-selective fluorescent reagents, as well as by cysteine-directed PEGylation. These two cysteine residues can also be re-ligated by means of a bifunctional cysteine cross-linking agent, dibromobimane, thereby both restoring a covalent linkage between the heavy and light chains at this site, far removed from the antigen binding site, and also introducing a fluorescent probe. There are many other research and clinical uses for these selectively partially reduced Fab fragments, including biotinylation, toxin and drug conjugation, and incorporation of radioisotopes, and this technique enables simple generation of very useful Fab fragment derivatives with many potential applications.

Proline residues link the active site to transmembrane domain movements in human nucleoside triphosphate diphosphohydrolase 3 (NTPDase3).

The active sites of the membrane-bound nucleoside triphosphate diphosphohydrolases (NTPDases) regulate and are regulated by coordinated and spatially distant movements of their transmembrane helices, modulating enzyme activity, and substrate specificity. Using site-directed mutagenesis, the roles of the conserved proline residues (N-terminal: P52 and P53; C-terminal: P472, P476, P481, P484, and P485) of human NTPDase3, located in the "linker regions" that connect the N- and C-terminal transmembrane helices with the extracellular active site, were examined. Single cysteine substitutions were strategically placed in the transmembrane domain (N-terminal helix: V42C; C-terminal helix: G489C) to serve as cross-linking "sensors" of helical interactions. These "sensor" background mutant proteins (V42C and G489C NTPDase3) are enzymatically active and are cross-linked by copper phenanthroline less efficiently in the presence of adenosine triphosphate (ATP). Proline to alanine substitutions at P53, P481, P484, and P485 in the V42C background, as well as P53, P481, and P484 in the G489C background, exhibited decreased nucleotidase activities. More importantly, alanine substitutions at P53 and P481 in the V42C background and P481 in the G489C background no longer exhibited the ATP-induced decrease in transmembrane cross-linking efficiency. Interestingly, the P485A mutation abolished oxidative cross-linking at G489C both in the presence and absence of ATP. Taken together, these results suggest a role for proline residues 53 and 481 in the linker regions of human NTPDase3 for coupling nucleotide binding at the enzyme active site to movements and/or rearrangements of the transmembrane helices necessary for optimal nucleotide hydrolysis.

Epitope mapping in cell surface proteins by site-directed masking: defining the structural elements of NTPDase3 inhibition by a monoclonal antibody.

We adapted the method of epitope mapping by site-directed masking, which was described for purified soluble antigens [Paus,D. and Winter,G. (2006) Proc. Natl Acad. Sci. USA, 103, 9172-9177.], to map the binding site of an inhibitory monoclonal antibody on the cell surface protein ecto-nucleotidase NTPDase3. Using homology modeling, we built a 3D structure of NTPDase3 and designed 21 single cysteine mutations distributed over the surface of the enzyme. The mutant proteins were expressed in cells, biotinylated with a cysteine-specific reagent, and then extracted with detergent and immobilized on streptavidin-coated plates. Tethering NTPDase3 via cysteine residues located in a surface patch near the active site cleft masked the epitope and blocked antibody binding, as evaluated by enzyme inhibition assay and by ELISA. We then constructed 18 single alanine substitution mutations within the defined patch and found that W403A, D414A, E415A and R419A decreased the inhibitory effect of the antibody, whereas the double mutation W403A/R419A abolished both antibody binding and enzyme inhibition, suggesting the critical role of these residues for interaction with the antibody. Lack of competition between the antibody and a non-hydrolyzable substrate analog AMPPCP, as well as location of the epitope adjacent to the active site, suggest a noncompetitive mechanism of inhibition by steric hindrance. The described technique should be useful for systematic epitope mapping in cell membrane proteins for which either a 3D structure is available, or a sufficiently accurate 3D model can be obtained by homology modeling.

Conserved polar residues stabilize transmembrane domains and promote oligomerization in human nucleoside triphosphate diphosphohydrolase 3.

Polar residues play essential roles in the functions of transmembrane helices by mediating and stabilizing their helical interactions. To investigate the structural and functional roles of the conserved polar residues in the N- and C-terminal transmembrane helices of human nucleoside triphosphate diphosphohydrolase 3 (NTPDase3) (N-terminus, S33, S39, T41, and Q44; C-terminus, T490, T495, and C501), each was singly mutated to alanine. The mutant proteins were analyzed for enzymatic activities, glycosylation status, expression level, and Triton X-100 detergent sensitivity. The Q44A mutation decreased Mg-ATPase activity by approximately 70% and abolished Triton X-100 detergent inhibition of Ca-dependent nucleotidase activities while greatly attenuating Triton X-100 inhibition of Mg-dependent nucleotidase activities. The polar residues were also mutated to cysteine, singly and in pairs, to allow a disulfide cross-linking strategy to map potential inter- and intramolecular hydrogen bond interactions. The results support the centrality of Q44 for the strong intermolecular interactions driving the association of the N-terminal helices of two NTPDase3 monomers in a dimer, and the possibility that T41 may play a role in the specificity of this interaction. In addition, S33 and C501 form an intramolecular association, while S39 and T495 may contribute to helical interactions involved in forming higher-order oligomers. Lastly, Tween 20 substantially and selectively increases NTPDase3 activity, mediated by the transmembrane helices containing the conserved polar residues. Taken together, the data suggest a model for putative hydrogen bond interactions of the conserved polar residues in the transmembrane domain of native, oligomeric NTPDase3. These interactions are important for proper protein expression, full enzymatic activity, and susceptibility to membrane perturbations.

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.

Characterization and importance of the dimer interface of human calcium-activated nucleotidase.

Human calcium-activated nucleotidase (CAN) exists as both a membrane-bound form in the endoplasmic reticulum and pre-Golgi intermediate membranes and as a secreted, soluble form. Although the wild-type human enzyme hydrolyzes ADP poorly, engineered soluble human proteins (SCANs) hydrolyze ADP much more efficiently, making them potentially useful therapeutic proteins for treatment of human clotting pathologies. According to the crystal structure and the recently identified dimeric nature of the soluble nucleotidase, the dimer interface contains a central core of hydrophobic residues. Previously, we demonstrated that the mutation of glutamic acid 130 (located in the dimer interface) to tyrosine increased both the tendency to form dimers and the ADPase activity. In the present study, we investigated the importance of the dimeric state for enzymatic activity and biological function in this nucleotidase by mutating isoleucine 170, which is located in the center of the hydrophobic core of the dimer interface. The results of analytical ultracentrifugation, chemical cross-linking, and tryptophan fluorescence analyses demonstrated that mutation of isoleucine 170 to either positively or negatively charged amino acids (lys or glu) disrupted the calcium-dependent dimerization in soluble CAN. Furthermore, these mutations decreased maximal ADPase activity for both the soluble and membrane-bound enzymes. Although not as critical as the hydrophobic interactions centered at isoleucine 170, the role of hydrophilic interactions in dimer formation was also demonstrated. Thus, mutation of aspartic acid 228 to threonine (D228T) decreased both the tendency to form dimers and ADPase activity, while double mutation of D228T/K224N largely restored the ability to form dimers and the ADPase activity, further indicating that the nucleotidase activity of CAN is linked to its quaternary structure. Since ADPase activity of the soluble form is crucial for its potential development as a therapeutic protein, these findings have implications for engineering the soluble human calcium-activated nucleotidase for clinical applications. In addition, future comparison of monomeric (I170K and I170E mutants) and dimeric (wild-type) crystal structures of SCAN will advance our understanding of its enzymatic mechanism and aid in engineering efforts.

Transient changes in the localization and activity of ecto-nucleotidases in rat hippocampus following lipopolysaccharide treatment.

The concentrations of extracellularly released nucleotides are controlled by metabolism via ecto-nucleotidases, but the precise physiological roles of the ecto-nucleoside triphosphate diphosphohydrolases in the modulation of purinergic receptor signalling are still unclear. Bacterial endotoxin lipopolysaccharide (LPS) treatment (administered intraperitoneally, 2 mg/kg body weight) of rats resulted in no significant changes in the overall ecto-nucleotidase activities of the hippocampus, however, LPS treatment did cause transient changes in the morphology of endothelial cells and pericytes and in the localization pattern of ecto-ATPase activity in rat hippocampus. The transient decrease in NTPDase1 (ecto-nucleoside triphosphate diphosphohydrolase1) activity, located on the luminal side of the endothelial cells, was balanced by increases in ecto-nucleotidase activities in pericytes and at other sites, consistent with an unchanged overall ecto-ATPase activity of the hippocampus. Since the transient loss of NTPDase1 activity was not accompanied by a loss of NTPDase1 protein, we hypothesize that LPS caused transient alterations in the lipid membranes, since NTPDase1 activity is known to be sensitive to changes in membrane structure via its transmembrane domains. After 2-3 days, the LPS-induced changes in cell morphology and ecto-nucleotidase localization disappeared. We conclude that a low dose of LPS causes transient changes in the localization pattern of ecto-nucleotidases in endothelial cells and pericytes, which, coupled with the observed cellular morphological changes, may indicate modified cellular signalling in the hippocampus.

Characterization of an alternative splice variant of human nucleoside triphosphate diphosphohydrolase 3 (NTPDase3): a possible modulator of nucleotidase activity and purinergic signaling.

Nucleoside triphosphate diphosphohydrolase 3 (NTPDase3) is a cell surface, membrane-bound enzyme that hydrolyzes extracellular nucleotides, thereby modulating purinergic signaling. An alternatively spliced variant of NTPDase3 was obtained and analyzed. This alternatively spliced variant, termed "NTPDase3beta", is produced through the use of an alternative terminal exon (exon 11) in place of the terminal exon (exon 12) in the full-length NTPDase3, now termed "NTPDase3alpha". This results in an expressed protein lacking the C-terminal cytoplasmic sequence, the C-terminal transmembrane helix, and apyrase conserved region 5. The cDNA encoding this truncated splice variant was detected in a human lung library by PCR. Like the full-length NTPDase3alpha, the alternatively spliced NTPDase3beta was expressed in COS cells after transfection, but only the full-length NTPDase3alpha is enzymatically active and properly trafficked to the plasma membrane. However, when the truncated NTPDase3beta was co-transfected with full-length NTPDase3alpha, there was a significant reduction in the amount of NTPDase3alpha that was properly processed and trafficked to the plasma membrane as active enzyme, indicating that the truncated form interferes with normal biosynthetic processing of the full-length enzyme. This suggests a role for the NTPDase3beta variant in the regulation of NTPDase3 nucleotidase activity, and therefore the control of purinergic signaling, in those cells and tissues expressing both NTPDase3alpha and NTPDase3beta.

Calcium-dependent dimerization of human soluble calcium activated nucleotidase: characterization of the dimer interface.

Mammals express a protein homologous to soluble nucleotidases used by blood-sucking insects to inhibit host blood clotting. These vertebrate nucleotidases may play a role in protein glycosylation. The activity of this enzyme family is strictly dependent on calcium, which induces a conformational change in the secreted, soluble human nucleotidase. The crystal structure of this human enzyme was recently solved; however, the mechanism of calcium activation and the basis for the calcium-induced changes remain unclear. In this study, using analytical ultracentrifugation and chemical cross-linking, we show that calcium or strontium induce noncovalent dimerization of the soluble human enzyme. The location and nature of the dimer interface was elucidated using a combination of site-directed mutagenesis and chemical cross-linking, coupled with crystallographic analyses. Replacement of Ile(170), Ser(172), and Ser(226) with cysteine residues resulted in calcium-dependent, sulfhydryl-specific intermolecular cross-linking, which was not observed after cysteine introduction at other surface locations. Analysis of a super-active mutant, E130Y, revealed that this mutant dimerized more readily than the wild-type enzyme. The crystal structure of the E130Y mutant revealed that the mutated residue is found in the dimer interface. In addition, expression of the full-length nucleotidase revealed that this membrane-bound form can also dimerize and that these dimers are stabilized by spontaneous oxidative cross-linking of Cys(30), located between the single transmembrane helix and the start of the soluble sequence. Thus, calcium-mediated dimerization may also represent a mechanism for regulation of the activity of this nucleotidase in the physiological setting of the endoplasmic reticulum or Golgi.

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.

Bacterial expression, folding, purification and characterization of soluble NTPDase5 (CD39L4) ecto-nucleotidase.

The ecto-nucleoside triphosphate diphosphohydrolases (eNTPDases) are a family of enzymes that control the levels of extracellular nucleotides, thereby modulating purinergically controlled physiological processes. Six of the eight known NTPDases are membrane-bound enzymes; only NTPDase 5 and 6 can be released as soluble enzymes. Here we report the first bacterial expression and refolding of soluble human NTPDase5 from inclusion bodies. The results show that NTPDase5 requires the presence of divalent cations (Mg2+ or Ca2+) for activity. Positive cooperativity with respect to hydrolysis of its preferred substrates (GDP, IDP and UDP) is observed, and this positive cooperativity is attenuated in the presence of nucleoside monophosphate products (e.g., GMP and AMP). In addition, comparing the biochemical properties of wild-type NTPDase5 and those of a mutant NTPDase5 (C15S, which lacks the single, non-conserved cysteine residue), also expressed in bacteria, suggests that Cys15 is not essential for either proper refolding or enzymatic activity (indicating this residue is not involved in a disulfide bond). Moreover, the substrate profile of bacterially expressed NTPDase5, as well as the C15S mutant, was determined to be similar to that of full-length, membrane-bound and soluble NTPDase5 expressed in mammalian COS cells.

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.

Bacterial expression and characterization of a novel, soluble, calcium-binding, and calcium-activated human nucleotidase.

A newly discovered human analogue of a bed bug apyrase, which we named hSCAN-1 for human soluble calcium-activated nucleotidase-1, was expressed in bacteria, refolded from inclusion bodies, purified, and characterized. This apyrase, which is distinct from the eNTPDases exemplified by the endothelial CD39 (NTPDase1) apyrase, is a 38 kDa monomeric enzyme capable of hydrolyzing a variety of nucleoside di- and triphosphates, but not monophosphates. Preferred substrates include GDP, UDP, and IDP, with a pH optimum for activity between 6 and 7. The specific activity and substrate preference of the bacterially expressed enzyme closely mimic those of the enzyme expressed in mammalian COS cells, as well as the enzyme synthesized in an in vitro bacterial expression system. This suggests that glycosylation and other posttranslational modifications that do not occur in bacteria are not necessary for nucleotidase activity or proper folding of this human apyrase. hSCAN-1 absolutely requires Ca(2+), but not Mg(2+) or other divalent cations analyzed, for enzymatic activity. Surprisingly, the activity does not increase in a quasi-linear fashion at sub-millimolar Ca(2+) concentrations, as would be expected if Ca(2+) were only used as a cosubstrate for the nucleotide substrate, but rather follows a sigmoidal curve. The intrinsic fluorescence and difference absorption studies of hSCAN-1 in the absence of nucleotides revealed Ca(2+)-induced changes in the environment of tryptophan and tyrosine residues with half-saturation at about 90 microM Ca(2+). NaCl increased the half-saturating Ca(2+) concentration needed for both structural changes detected by optical spectroscopy and enzymatic activation of hSCAN-1 detected by nucleotidase assay. These results suggest that Ca(2+) triggers a conformational change in hSCAN-1, converting the enzymatically inactive protein to the active enzyme, in addition to forming the metal-nucleotide substrate complex necessary for nucleotidase activity.

Cell-type specificity of ectonucleotidase expression and upregulation by 2,3,7,8-tetrachlorodibenzo-p-dioxin.

We report here that induction of ectoATPase by 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) is cell-type specific and not a generalized response to aryl hydrocarbon (Ah) receptor activation. TCDD increased [14C]-ATP and -ADP metabolism in two mouse hepatoma lines, Hepa1c1c7 and Hepa1-6 cells, but not in human hepatoma HepG2 or HuH-7 cells, human umbilical vein endothelial cells (HUVEC), chick hepatoma (LMH) cells, or chick primary hepatocytes or cardiac myocytes, even though all of those cell types were Ah receptor-responsive, as evidenced by cytochrome P4501A induction. To determine whether the differences in ectonucleotidase responsiveness to TCDD might be related to differences in cell-type ectonucleotidase expression, ATP and ADP metabolite patterns, the products of several classes of ectonucleotidases including ectonucleoside triphosphate diphosphohydrolases (E-NTPDases), ectophosphodiesterase/pyrophosphatases (E-NPP enzymes) and ectoalkaline phosphatase activities were examined. Those patterns, together with results of enzyme assays, Western blotting, or semiquantitative RT-PCR show that NTPDase2 is the main ectonucleotidase for murine and human hepatoma cells, NTPDase3 for chick hepatocytes and LMH cells, and an E-NPP enzyme for chick cardiac myocytes. Evidence for NTPDase2 expression was lacking in all cells except the mouse and human hepatoma cells. TCDD increased expression of the NTPDase2 gene but only in the mouse and not in the human hepatoma cells. TCDD did not increase NTPDase3, NTPDase1, E-NPP, or alkaline phosphatase in any of the cell types examined. The failure of TCDD to increase ATP metabolism in HUVEC, chick LMH cells, hepatocytes, and cardiac myocytes can be attributed to their lack of NTPDase2 expression, while the increase in ATP metabolism by TCDD in the mouse but not the human hepatoma cells can be explained by differences in TCDD effects on mouse and human hepatoma NTPDase2 gene expression. In addition to characterizing effects of TCDD on ectonucleotidases, these studies reveal major differences in the complements of ectonucleotidases present in different cell types. It is likely that such differences are important for cell-specific susceptibility to extracellular nucleotide toxicity and responses to purinergic signaling.

Cloning, expression, and characterization of a soluble calcium-activated nucleotidase, a human enzyme belonging to a new family of extracellular nucleotidases.

The salivary apyrases of blood-feeding arthropods are nucleotide-hydrolyzing enzymes implicated in the inhibition of host platelet aggregation through the hydrolysis of extracellular adenosine diphosphate. A human cDNA homologous to the apyrase cDNA of the blood-feeding bed bug was identified, revealing an open reading frame encoding a 371-amino acid protein. A cleavable signal peptide generates a secreted protein of 333 residues with a predicted core molecular mass of 37,193 Da. Expression in COS-1 cells produced a secreted apyrase in the cell media. The ADPase and ATPase activities were dependent upon calcium, with a pH optimum between pH 6.2 and 7.2. Interestingly, the preferred substrate was not ADP, as might be expected for an enzyme modulating platelet aggregation, but rather UDP, followed by GDP, UTP, GTP, ADP, and ATP. The nucleotidase did not hydrolyze nucleoside monophosphates. Size-exclusion chromatography and Western blot analysis revealed a molecular mass of approximately 34-37 kDa. Treatment of the enzyme with peptide N-glycosidase F indicated that the protein is glycosylated. Northern analysis identified the transcript in a range of human tissues, including testis, placenta, prostate, and lung. No traditional apyrase-conserved regions or nucleotide-binding domains were identified in this human enzyme, indicating membership in a new family of extracellular nucleotidases.

Identification of cysteine residues responsible for oxidative cross-linking and chemical inhibition of human nucleoside-triphosphate diphosphohydrolase 3.

Cysteine-to-serine mutations were constructed to test the functional and structural significance of the three non-extracellular cysteine residues in ecto-nucleoside-triphosphate diphosphohydrolase 3 (eNTPDase3). None of these cysteines were found to be essential for enzyme activity. However, Cys(10), located on the short N-terminal cytoplasmic tail, was found to be responsible for dimer formation occurring via oxidation during membrane preparation as well as for dimer cross-linking resulting from exogenously added sulfhydryl-specific cross-linking agents. The resistance to further cross-linking of these dimers into higher order oligomers by lysine-specific cross-linkers suggests that this enzyme may form its native tetrameric structure as a "dimer of dimers" with nonequivalent interactions between subunits. Cys(501), located in the hydrophobic C-terminal membrane-spanning domain of eNTPDase3, was found to be the site of chemical modification by a sulfhydryl-specific reagent, p-chloromercuriphenylsulfonic acid (pCMPS), leading to inhibition of enzyme activity. The effect of pCMPS was negligible after dissociation of the enzyme into monomers by Triton X-100, suggesting that the mechanism of inhibition is dependent on the oligomeric structure. Because Cys(501) is accessible for modification by the membrane-impermeant reagent pCMPS, we hypothesize that eNTPDase3 (and possibly other eNTPDases) contains a water-filled crevice allowing access of water and hydrophilic compounds to at least part of the protein's C-terminal membrane-spanning helix.