Distinctive roles of endoplasmic reticulum and golgi glycosylation in functional surface expression of mammalian E-NTPDase1, CD39

Various N-glycoforms differentially upregulate E-NTPDase activity of the NTPDase3/CD39L3 ecto-enzymatic domain

The GDA1/CD39 ecto-nucleoside triphosphate diphosphosphohydrolase (E-NTPDase) superfamily is a group of eight heavily glycosylated ecto-enzymes that hydrolyze extracellular nucleosides di- and tri-phosphates in the presence of divalent cations, to generate the monophosphate derivatives. This catalytic process differentially regulates a complex array of purinergic signaling responses. NTPDase3/CD39L3is dominantly expressed in pancreatic islet cells, where it may regulate insulin secretion, and has seven N-linked glycosylation sites with four close to five highly conserved domains called "apyrase conserved regions" (ACRs). In a manner similar to CD39, NTPDase3/CD39L3 uses ATP as its preferential substrate and also possesses significant activities toward other triphosphate and diphosphate nucleosides. To understand the mechanism of the ecto-NTPDase activity and substrate specificity, potentially impacted by N-glycans, we have generated soluble enzymatic domains of NTPDase3/CD39L3 in human embryotic kidney cells with four different glycan modifications. These include mannose5-9 glycans with kifunesine treatment, single GlcNAc-Asn by treatment with EndoH, de-glycosylated form by treatment with PNGaseF, and wild-type glycans. Our functional data indicate that the non-glycosylated NTPDase3/CD39L3 ecto-enzymatic domain retains activity, but that N-glycan attachments, such as the GlcNAc-Asn, substantially upregulate specific NTPDase activity by 2-20 fold. Both the Vmax and the Km on di- or tri-phosphate nucleosides are substantially and differentially altered by the glycan attachments. Structural modeling analysis based on putative structures derived from bacterial-originated CD39 domain proteins suggests that N-glycan modifications at Asn149 next to ACR2 and/or Asn454, N-terminal to ACR5 have critical roles in regulating the catalytic pocket of NTPDase3/CD39L3. Our data provide both new insights into the enzymatic mechanisms of NTPDase family members and further evidence that N-glycans directly modulate functional ectonucleotidase activities.

N-glycosylation of human sphingomyelin phosphodiesterase acid-like 3A (SMPDL3A) is essential for stability, secretion and activity

Sphingomyelin phosphodiesterase acid-like 3A (SMPDL3A) is a recently identified phosphodiesterase, which is a secreted N-linked glycoprotein. SMPDL3A is highly homologous to acid sphingomyelinase (aSMase), but unlike aSMase cannot cleave sphingomyelin. Rather, SMPDL3A hydrolyzes nucleotide tri- and diphosphates and their derivatives. While recent structural studies have shed light on these unexpected substrate preferences, many other aspects of SMPDL3A biology, which may give insight into its function in vivo, remain obscure. Here, we investigate the roles of N-glycosylation in the expression, secretion and activity of human SMPDL3A, using inhibitors of N-glycosylation and site-directed mutagenesis, with either THP-1 macrophages or CHO cells expressing human SMPDL3A. Tunicamycin (TM) treatment resulted in expression of non-glycosylated SMPDL3A that was not secreted, and was largely degraded by the proteasome. Proteasomal inhibition restored levels of SMPDL3A in TM-treated cells, although this non-glycosylated protein lacked phosphodiesterase activity. Enzymatic deglycosylation of purified recombinant SMPDL3A also resulted in significant loss of phosphodiesterase activity. Site-directed mutagenesis of individual N-glycosylation sites in SMPDL3A identified glycosylation of Asn69 and Asn222 as affecting maturation of its N-glycans and secretion. Glycosylation of Asn356 in SMPDL3A, an N-linked site conserved throughout the aSMase-like family, was critical for protection against proteasomal degradation and preservation of enzymatic activity. We provide the first experimental evidence for a predicted 22 residue N-terminal signal peptide in SMPDL3A, which is essential for facilitating glycosylation and is removed from the mature protein secreted from CHO cells. In conclusion, site-specific N-glycosylation is essential for the intracellular stability, secretion and activity of human SMPDL3A.

Breakthroughs spotlighting roles for extracellular nucleotides and apyrases in stress responses and growth and development

Animal and plant cells release nucleotides into their extracellular matrix when touched, wounded, and when their plasma membranes are stretched during delivery of secretory vesicles and growth. These released nucleotides then function as signaling agents that induce rapid increases in the concentration of cytosolic calcium, nitric oxide and superoxide. These, in turn, are transduced into downstream physiological changes. These changes in plants include changes in the growth of diverse tissues, in gravitropism, and in the opening and closing of stomates. The concentration of extracellular nucleotides is controlled by various phosphatases, prominent among which are apyrases EC 3.6.1.5 (nucleoside triphosphate diphosphohydrolases, NTPDases). This review provides phylogenetic and pHMM analyses of plant apyrases as well as analysis of predicted post-translational modifications for Arabidopsis apyrases. This review also summarizes and discusses recent advances in research on the roles of apyrases and extracellular nucleotides in controlling plant growth and development. These include new findings that document how apyrases and extracellular nucleotides control auxin transport, modulate stomatal aperture, and mediate biotic and abiotic stress responses, and on how apyrase suppression leads to growth inhibition.

Cellular function and molecular structure of ecto-nucleotidases

Ecto-nucleotidases play a pivotal role in purinergic signal transmission. They hydrolyze extracellular nucleotides and thus can control their availability at purinergic P2 receptors. They generate extracellular nucleosides for cellular reuptake and salvage via nucleoside transporters of the plasma membrane. The extracellular adenosine formed acts as an agonist of purinergic P1 receptors. They also can produce and hydrolyze extracellular inorganic pyrophosphate that is of major relevance in the control of bone mineralization. This review discusses and compares four major groups of ecto-nucleotidases: the ecto-nucleoside triphosphate diphosphohydrolases, ecto-5'-nucleotidase, ecto-nucleotide pyrophosphatase/phosphodiesterases, and alkaline phosphatases. Only recently and based on crystal structures, detailed information regarding the spatial structures and catalytic mechanisms has become available for members of these four ecto-nucleotidase families. This permits detailed predictions of their catalytic mechanisms and a comparison between the individual enzyme groups. The review focuses on the principal biochemical, cell biological, catalytic, and structural properties of the enzymes and provides brief reference to tissue distribution, and physiological and pathophysiological functions.

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.

Expression, purification and crystallization of the ecto-enzymatic domain of rat E-NTPDase1 CD39

CD39 is a prototype member of the ecto-nucleoside triphosphate diphosphohydrolase family that hydrolyzes extracellular nucleoside diphosphates and triphosphates in the presence of divalent cations. Here, the expression, purification and crystallization of the ecto-enzymatic domain of rat CD39, sCD39, are described. The 67 kDa secreted soluble glycoprotein was recombinantly overexpressed in a glycosylation mutant CHO line, Lec.3.2.8.1, and purified from conditioned media. Diffraction-quality crystals of sCD39 were produced by the vapor-diffusion method using PEG 3350 and ammonium dihydrogen phosphate as precipitants. The enzyme crystallized in a primitive trigonal form in space group P3(2), with unit-cell parameters a = b = 118.1, c = 81.6 A and with two sCD39 copies in the asymmetric unit. Several low- to medium-resolution diffraction data sets were collected using an in-house X-ray source. Analysis of the intensity statistics showed that the crystals were invariably merohedrally twinned with a high twin fraction. For initial phasing, a molecular-replacement search was performed against the complete 3.2 A data set using a maximum-likelihood molecular-replacement method as implemented in Phaser. The initial model of the two sCD39 monomers was placed into the P3(2) lattice and rigid-body refined and position-minimized with PHENIX.

Cloning, molecular characterization and expression of ecto-nucleoside triphosphate diphosphohydrolase-1 from Torpedo electric organ

During synaptic transmission large amounts of ATP are released from pre- and post-synaptic sources of Torpedo electric organ. A chain reaction sequentially hydrolyses ATP to adenosine, which inhibits acetylcholine secretion. The first enzyme implicated in this extracellular ATP hydrolysis is an ecto-nucleoside triphosphate diphosphohydrolase (E-NTPDase) that dephosphorylates both ATP and ADP to AMP. This enzyme has been biochemically characterized in the synaptosomal fraction of Torpedo electric organ, having almost equal affinity for ATP as for ADP, a fact that pointed to the type-1 NTPDase enzyme. In the present work we describe the cloning and molecular characterization of the cDNA for an NTPDase from Torpedo marmorata electric organ. The clone, obtained using the RACE-PCR technique, contains and open-reading frame of 1506bp and encodes a 502 amino acids protein that exhibits high homology with other NTPDases1 from vertebrates previously identified, including those of zebrafish and Xenopus, as well as human, rat and mouse. Topology analyses revealed the existence of two transmembrane regions, two short cytoplasmic tails and a long extracellular domain containing five apyrase-conserved regions. Gene expression studies revealed that this gene is expressed in all the Torpedo tissues analyzed. Finally, activity and cellular localization of the protein encoded by this newly cloned cDNA was assessed by heterologous expression experiments involving COS-7 and HeLa cells.

The Structure of the Lingo-1 Ectodomain, a Module Implicated in Central Nervous System Repair Inhibition

Nogo receptor (NgR)-mediated control of axon growth relies on the central nervous system-specific type I transmembrane protein Lingo-1. Interactions between Lingo-1 and NgR, along with a complementary co-receptor, result in neurite and axonal collapse. In addition, the inhibitory role of Lingo-1 is particularly important in regulation of oligodendrocyte differentiation and myelination, suggesting that pharmacological modulation of Lingo-1 function could be a novel approach for nerve repair and remyelination therapies. Here we report on the crystal structure of the ligand-binding ectodomain of human Lingo-1 and show it has a bimodular, kinked structure composed of leucine-rich repeat (LRR) and immunoglobulin (Ig)-like modules. The structure, together with biophysical analysis of its solution properties, reveals that in the crystals and in solution Lingo-1 persistently associates with itself to form a stable tetramer and that it is its LRR-Ig-composite fold that drives such assembly. Specifically, in the crystal structure protomers of Lingo-1 associate in a ring-shaped tetramer, with each LRR domain filling an open cleft in an adjacent protomer. The tetramer buries a large surface area (9,200 A2) and may serve as an efficient scaffold to simultaneously bind and assemble the NgR complex components during activation on a membrane. Potential functional binding sites that can be identified on the ectodomain surface, including the site of self-recognition, suggest a model for protein assembly on the membrane.