Molecular cloning, characterization, and chromosomal localization of the mouse homologue of CD84, a member of the CD2 family of cell surface molecules

 CD84 is a member of the immunoglobulin gene superfamily (IgSF) with two Ig-like domains expressed primarily on B lymphocytes and macrophages. Here we describe the cloning of the mouse homologue of human CD84. Mouse CD84 cDNA clones were isolated from a macrophage library. The nucleotide sequence of mouse CD84 was shown to include an open reading frame encoding a putative 329 amino acid protein composed of a 21 amino acid leader peptide, two extracellular immunoglobulin (Ig)-like domains, a hydrophobic transmembrane region, and an 87 amino acid cytoplasmic domain. Mouse CD84 shares 57.3% amino acid sequence identity (88.7%, considering conservative amino acid substitutions) with the human homologue. Chromosome localization studies mapped the mouse CD84 gene to distal chromosome 1 adjacent to the gene for Ly-9, placing it close to the region where other members of the CD2 IgSF (CD48 and 2B4) have been mapped. Northern blot analysis revealed that the expression of mouse CD84 was predominantly restricted to hematopoietic tissues. Two species of mRNA of 3.6 kilobases (kb) and 1.5 kb were observed. The finding that the pattern of expression was restricted to the hematopoietic system and the conserved sequence of the mouse CD84 homologue suggests that the function of the CD84 glycoprotein may be similar in humans and mice. Received: 1 July 1998 / Revised: 31 August 1998     

Transmembrane domains confer different substrate specificities and adenosine diphosphate hydrolysis mechanisms on CD39, CD39L1, and chimeras

Members of the ecto-nucleoside triphosphate diphosphohydrolase (eNTPDase) family exhibit distinctive substrate specificities, but how such specificities are achieved by enzymes with identical putative catalytic domains is unknown. Previously we showed that H59G substitution changes CD39 from an apyrase to an adenosine diphosphatase (ADPase) in a manner that depends on intact associations of both transmembrane domains with the membrane. Here we show that the extracellular domain of CD39L1 ecto-adenosine triphosphatase (ecto-ATPase) has the same 3:1 ATP:ADP hydrolysis ratio as the extracellular domain of CD39, suggesting that the transmembrane domains are required to confer the native substrate specificities on each enzyme. As in CD39, H50G substitution has little effect on the activity of the CD39L1 extracellular domain or solubilized monomers. However, H50G substitution diminishes both ATPase and ADPase activities of native CD39L1, in contrast to its selective effect on ATPase activity in CD39, suggesting that the transmembrane domains confer different ADP hydrolysis mechanisms on CD39 and CD39L1. We then show that the transmembrane domains of CD39L1 can substitute for those of CD39 in conferring native CD39 substrate specificity and regulation of H59 but that the transmembrane domains of CD39 confer neither CD39 nor CD39L1 properties on the CD39L1 extracellular domain. These results suggest that non-apyrase conserved region residues in the extracellular domain contain the information specifying CD39 native properties but have a nonspecific requirement for two transmembrane domains to manifest the information.     

Isolation and characterization of mouse CD7 cDNA

The human CD7 antigen is a glycoprotein, M _r 40 000, expressed on the surface of peripheral blood T-lymphocytes and thymocytes, and is the earliest surface antigen to appear on T-cell lineage cells. In this study, putative mouse CD7 cDNA was identified based on its similarities with human CD7. Five independent clones originating from the same mRNA species were isolated (designated as mCD7) by screening a mouse thymocyte cDNA library with human CD7 cDNA, J61, under moderate stringency. The longest insert of a 995 base pair had an open reading frame of 210 amino acids. Northern blot analysis using the mouse CD7 cDNA probe demonstrated a single 1.2 kilobase mRNA ni the thymus, spleen, bone marrow, and small intestine. The protein deduced from mCD7 cDNA consisted of the leader, extracellular, transmembrane, and cytoplasmic domains of 24, 126, 21, and 39 amino acids, respectively, based on the hydrophobicity plot and the structure of human CD7. The extracellualr domain contained three potential N-glycosilation sites, while the cytoplasmic domain contained one potential protein kinase C phosphorylation site. The amino acid sequence had 45.5% similarity with human CD7, while the similarities for the individual domains ranged from 49.2% to 63.2%. The six highly conserved regions, which may possibly be involved with still unknown CD7-mediated functions, were located in the extracellular and cytoplasmic domains.The nucleotide sequence data reported in this paper have seen submitted to the GenBank, DDBJ, and EMBL nucleotide sequence database and have been assigned the accession number D10329.     

CD39L2, a gene encoding a human nucleoside diphosphatase, predominantly expressed in the heart

E-NTPDases are extracellular enzymes that hydrolyze nucleotides. The human E-NTPDase gene family currently consists of five reported members (CD39, CD39L1, CD39L2, CD39L3, and CD39L4). Both membrane-bound and secreted family members have been predicted by encoded transmembrane and leader peptide motifs. In this report, we demonstrate that the human CD39L2 gene is expressed predominantly in the heart. In situ hybridization results from heart indicate that the CD39L2 message is expressed in muscle and capillary endothelial cells. We also show that the CD39L2 gene encodes an extracellular E-NTPDase. Flow cytometric experiments show that transiently expressed CD39L2 is present on the surface of COS-7 cells. Transfected cells also produce recombinant glycosylated protein in the medium, and this process can be blocked by brefeldin A, an inhibitor of the mammalian secretory pathway. The enzymology of CD39L2 shows characteristic features of a typical E-NTPDase, but with a much higher degree of specificity for NDPs over NTPs as enzymatic substrates. The kinetics of the ADPase activity exhibit positive cooperativity. The predominance of CD39L2 expression in the heart supports a functional role in regulating platelet activation and recruitment in this organ.     

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.     

Structure of the genes encoding the CD19 antigen of human and mouse B lymphocytes

CD19 is a B lymphocyte cell-surface marker that is expressed early during pre-B-cell differentiation with expression persisting until terminal differentiation into palsma cells. CD19 is a member of Ig gnee superfamily with two extreacellular Ig-like domains separated amino acid cytoplasmic domain. In this study, Southern blot analysis revelaed that the human and mouse CD19 genes were compact single copy genes. Both the human and mouse CD19 genes were isolated and the nucleotide sequences flanking each exon were determined. Both genes were composed of 15 exons and spanned 8 kilobases (kb) of DNA in human and 6 kb in mouse. The positions of exon-intron boundaries were identical between human and mouse and correlated with the putative functional domains of the CD19 protein. The 200 bp region 5 of the putative translation initiation AUG codon as well conserved in sequence between human and mouse and contained potential trasncription regulatory elements. In addition, the 3 untranslated regions (UT) of the CD19 genes following the termination codon were conservedf in sequence. The high level conservation of nucleotide sequences between species in all exons and 5 and 3 UT suggests that expression of the CD19 gene may be regulated in a similar fashion in human and mouse.The nucleotide sequence database reported in this paper have been submitted to the GenBank nucleotide sequence database and have been assigned the accession numbers: human CD19 gnee, M62544 to M62550; mouse CD19 gene, M62551 to M62553.     

Biochemical characterization of CD39L4

Nucleotides are involved in regulating a number of important processes ranging from inflammation to platelet aggregation. Enzymes that can modulate levels of nucleotides in the blood therefore represent important regulatory components in these physiological systems. CD39L4 is a soluble E-nucleoside triphosphate dephosphohydrolase (E-NTPDase) with specificity for nucleotide diphosphates (NDPs). In this study, stable mammalian and insect cell lines were generated expressing CD39L4 protein to purify and characterize the recombinant protein. We demonstrate that recombinant CD39L4 protein expressed in human embryonic carcinoma 293 cells is glycosylated by comparing the molecular masses before and after glycosidase treatment. Activity measurements of CD39L4 isolated from tunicamycin-treated, transiently transfected COS-7 cells indicate that glycosylation is not required for full ADPase activity. Recombinant human CD39L4 protein isolated from stable insect cells was glycosylated differently, but also demonstrated relative activity comparable to that of the mammalian protein. When denatured by SDS under nonreducing conditions, a fraction of the CD39L4 protein migrates as a 110 kDa disulfide-linked dimer. We determined that the monomer is the most active form of CD39L4 by measuring the activity of sucrose density gradient fractions of monomers and partially purified dimers. The physiological significance of the biochemical and enzymatic characterization is discussed.     

CD39-adenosinergic axis in renal pathophysiology and therapeutics

Extracellular ATP interacts with purinergic type 2 (P2) receptors and elicits many crucial biological functions. Extracellular ATP is sequentially hydrolyzed to ADP and AMP by the actions of defined nucleotidases, such as CD39, and AMP is converted to adenosine, largely by CD73, an ecto-5′-nucleotidase. Extracellular adenosine interacts with P1 receptors and often opposes the effects of P2 receptor activation. The balance between extracellular ATP and adenosine in the blood and extracellular fluid is regulated chiefly by the activities of CD39 and CD73, which constitute the CD39-adenosinergic axis. In recent years, several studies have shown this axis to play critical roles in transport of water/sodium, tubuloglomerular feedback, renin secretion, ischemia reperfusion injury, renal fibrosis, hypertension, diabetic nephropathy, transplantation, inflammation, and macrophage transformation. Important developments include global and targeted gene knockout and/or transgenic mouse models of CD39 or CD73, biological or small molecule inhibitors, and soluble engineered ectonucleotidases to directly impact the CD39-adenosinergic axis. This review presents a comprehensive picture of the multiple roles of CD39-adenosinergic axis in renal physiology, pathophysiology, and therapeutics. Scientific advances and greater understanding of the role of this axis in the kidney, in both health and illness, will direct development of innovative therapies for renal diseases.     

Various <Emphasis Type="Italic">N</Emphasis>-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 mannose_5–9 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.     

Crowding within synaptic junctions influences the degradation of nucleotides by CD39 and CD73 ectonucleotidases

Synapsed cells can communicate using exocytosed nucleotides like adenosine triphosphate (ATP). Ectonucleotidases localized to synaptic junctions degrade nucleotides into metabolites like adenosine monophosphate (AMP) or adenosine. Oftentimes nucleotide degradation occurs in a sequential manner, of which ATP degradation by CD39 and CD73 is a representative example. Here, CD39 first converts ATP and adenosine diphosphate (ADP) into AMP, after which AMP is dephosphorylated into adenosine by CD73. Hence, the concerted activity of CD39 and CD73 can help shape cellular responses to extracellular ATP. In a previous study, we demonstrated that coupled CD39 and CD73 activity within synapse-like junctions is strongly controlled by the enzymes' co-localization, their surface charge densities, and the electrostatic potential of the surrounding cell membranes. In this study, we demonstrate that crowders within synaptic junctions, which can include globular proteins like cytokines and membrane-bound proteins, impact coupled CD39 and CD73 ectonucleotidase activity and, in turn, the availability of intrasynapse ATP. Specifically, we developed a spatially explicit, reaction-diffusion model for the coupled conversion of ATP → AMP and AMP → adenosine in a model synaptic junction with crowders that is solved via the finite element method. Our modeling results suggest that the association rate for ATP to CD39 is strongly influenced by the density of intrasynaptic protein crowders, as increasing crowder density generally suppressed ATP association kinetics. Much of this suppression can be rationalized based on a loss of configurational entropy. The surface charges of crowders can further influence the association rate, with the surprising result that favorable crowder-nucleotide electrostatic interactions can yield CD39 association rates that are faster than crowder-free configurations. However, attractive crowder-nucleotide interactions decrease the rate and efficiency of adenosine production, which in turn increases the availability of ATP and AMP within the synapse relative to crowder-free configurations. These findings highlight how CD39 and CD73 ectonucleotidase activity, electrostatics, and crowding within synapses influence the availability of nucleotides for intercellular communication.     

Polymorphism of chicken CD8-alpha, but not CD8-beta

 We report here the structural basis of CD8 polymorphism in the chicken. Three chicken strains (RPRL Line 7, H.B15.H7, and H.B15.H12) have 14 nucleotide differences in the CD8A cDNA sequence causing eight amino acid replacements in the extracellular part of the molecule. Only two amino acid replacements and four silent mutations were observed in the CD8B cDNA sequence in one (H7) of the strains. Substitutions in CD8α were solely responsible for the binding of CD8-specific monoclonal antibodies, as detected by cDNA expression in COS cells. The majority of the amino acid substitutions are located in the immunoglobulin V-like domain and three of the changes (residues 30, 34, and 58) are situated in the putative major histocompatibility complex class I binding CDR1 and CDR2 regions of the chicken CD8α. CD8A polymorphism has not been reported in other species and this suggests that CD8A and CD8B have evolved under different selective pressures in the chicken. Received: 28 February 1997 / Revised: 19 April 1997     

Beyond ecto-nucleotidase: CD39 defines human Th17 cells with CD161

CD39/ENTPD1 is a prototypic member of the ectonucleoside triphosphate diphosphohydrolase (ENTPDase) family on cell surface. CD39 has been reported to be a marker of regulatory immune cells and catalyzes extracellular hydrolysis of nucleotides to generate AMP and, in tandem with CD73, adenosine. We have recently found in addition that co-expression of CD39 and CD161 by human CD4⁺ T cells may become a biomarker of human Th17 cells. CD39 and CD161 have direct interactions that are further linked with acid sphingomyelinase (ASM). Upon activation of CD39 and CD161, the molecular interactions boost ASM bio-activity, which generates cellular ceramide to further mediate downstream signals inclusive of STAT3 and mTOR. We suggest modulation of human Th17 responsiveness by CD39 and CD161 and describe novel molecular mechanisms integrating elements of both extracellular nucleotide and sphingolipid homeostasis that are pivotal in the control of human Th17 cells and which could have therapeutic potential.     

Cloning,expression, and characterization of fugu CD4, the first ectothermic animal CD4

We have cloned and sequenced the first ectothermic animal CD4 gene from fugu, Takifugu rubripes, using a public database of the third draft sequence of the fugu genome. The fugu CD4 gene encodes a predicted protein of 463 amino acids containing four extracellular immunoglobulin (Ig)-like domains, a transmembrane region, and a cytoplasmic tail. Fugu CD4 shares low identity of about 15–20% with avian and mammalian CD4 proteins. Unlike avian and mammalian CD4, fugu CD4 lacks the Cys pair of the first Ig-like domain, but has a unique possible disulfide bond in the third domain. These differences suggest that fugu CD4 may have a different structure that could affect binding of major histocompatibility complex class II molecules and subsequent T-cell activation. In the putative fugu cytoplasmic region, the protein tyrosine kinase p56^lck binding motif is conserved. The predicted fugu CD4 gene is composed of 12 exons, differing from other CD4 genes, but showing conserved synteny and many conserved sequence motifs in the promoter region. RT-PCR analysis demonstrated that the fugu CD4 gene is expressed predominantly in lymphoid tissues. We also show that fugu CD4 can be expressed on the surface of cells via transfection. Molecular characterization of CD4 in fish provides insights into the evolution of both the CD4 molecule and the immune system.