Molecular cloning and characterization of carp (Cyprinus carpio L.) CD8beta and CD4-like genes

Partial cDNA sequences of both CD8beta and CD4-like (CD4L) genes of common carp (Cyprinus carpio L.) were isolated from thymus cDNA library by the method of suppression subtractive hybridization (SSH). Subsequently the full length cDNAs of carp CD8beta and CD4L were obtained by means of 3' RACE and 5' RACE, respectively. The full length cDNA of carp CD8beta is 1164 bp and encodes 207 amino acids including a signal peptide region of 24 amino acids, a transmembrane region of 23 amino acids from aa 167 to aa189 and an immunoglobulin V-set from aa 19 to aa 141. Similar to other species CD8betas, carp CD8beta also lacks p56(lck) domain in the cytoplasmic region. The full length cDNA of carp CD4L is 2001 bp and encodes 458 amino acids including four immunoglobulin (Ig)-like domains in the extracellular region, a transmembrane region of 23 amino acids at the C-terminal region from aa 402 to aa 424 and a cytoplasmic tail. Similar to mammalian, avian CD4s and fugu CD4L, carp CD4L also has the conserved p56(lck) tyrosine kinase motif (C-X-C) in the cytoplasmic region. RT-PCR analysis demonstrated that carp CD8beta and CD4L genes were both expressed predominantly in thymus. The results from this study can be used to understand the evolution of both the CD8beta and CD4 molecules which can be used as markers for cytotoxic and helper T cells in carp.     

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     

Costimulatory receptors in a teleost fish: typical CD28, elusive CTLA4

T cell activation requires both specific recognition of the peptide-MHC complex by the TCR and additional signals delivered by costimulatory receptors. We have identified rainbow trout sequences similar to CD28 (rbtCD28) and CTLA4 (rbtCTLA4). rbtCD28 and rbtCTLA4 are composed of an extracellular Ig-superfamily V domain, a transmembrane region, and a cytoplasmic tail. The presence of a conserved ligand binding site within the V domain of both molecules suggests that these receptors likely recognize the fish homologues of the B7 family. The mRNA expression pattern of rbtCD28 and rbtCTLA4 in naive trout is reminiscent to that reported in humans and mice, because rbtCTLA4 expression within trout leukocytes was quickly up-regulated following PHA stimulation and virus infection. The cytoplasmic tail of rbtCD28 possesses a typical motif that is conserved in mammalian costimulatory receptors for signaling purposes. A chimeric receptor made of the extracellular domain of human CD28 fused to the cytoplasmic tail of rbtCD28 promoted TCR-induced IL-2 production in a human T cell line, indicating that rbtCD28 is indeed a positive costimulator. The cytoplasmic tail of rbtCTLA4 lacked obvious signaling motifs and accordingly failed to signal when fused to the huCD28 extracellular domain. Interestingly, rbtCTLA4 and rbtCD28 are not positioned on the same chromosome and thus do not belong to a unique costimulatory cluster as in mammals. Finally, our results raise questions about the origin and evolution of positive and negative costimulation in vertebrate immune systems.     

Structural characterization of the transmembrane and cytoplasmic domains of human CD4

Cluster determinant 4 (CD4) is a type I transmembrane glycoprotein of 58 kDa. It consists of an extracellular domain of 370 amino acids, a short transmembrane region, and a cytoplasmic domain of 40 amino acids at the C-terminal end. We investigated the structure of the 62 C-terminal residues of CD4, comprising its transmembrane and cytoplasmic domains. The five cysteine residues of this region have been replaced with serine and histidine residues in the polypeptide CD4mut. Uniformly ¹⁵N and ¹³C labeled protein was recombinantly expressed in E. coli and purified. Functional binding activity of CD4mut to protein VpU of the human immunodeficiency virus type 1 (HIV-1) was verified. Close to complete NMR resonance assignment of the ¹H, ¹³C, and ¹⁵N spins of CD4mut was accomplished. The secondary structure of CD4mut in membrane simulating dodecylphosphocholine (DPC) micelles was characterized based on secondary chemical shift analysis, NOE-based proton-proton distances, and circular dichroism spectroscopy. A stable transmembrane helix and a short amphipathic helix in the cytoplasmic region were identified. The fractional helicity of the cytoplasmic helix appears to be stabilized in the presence of DPC micelles, although the extension of this helix is reduced in comparison to previous studies on synthetic peptides in aqueous solution. The role of the amphipathic helix and its potentially variable length is discussed with respect to the biological functions of CD4.     

Molecular cloning and characterization of CD4 in an aquatic mammal, the white whale Delphinapterus leucas

 Given the importance of the cell surface recognition protein, CD4, in immune function, the cloning and characterization of CD4 at the molecular level from an odontocete cetacean, the white whale (Delphinapterus leucas), was carried out. Whale CD4 cDNA contains 2662 base pairs and translates into a protein containing 455 amino acids. Whale CD4 shares 64% and 51% identity with the human and mouse CD4 protein, respectively, and is organized in a similar manner. Unlike human and mouse, however, the cytoplasmic domain, which is highly conserved, contains amino acid substitutions unique to whale. Moreover, only one of the seven potential N-linked glycosylation sites present in whale is shared with human and mouse. Evolutionarily, the whale CD4 sequence is most similar to pig and structurally similar to dog and cat, in that all lack the cysteine pair in the V2 domain. These differences suggest that CD4 may have a different secondary structure in these species, which may affect binding of class II and subsequent T-cell activation, as well as binding of viral pathogens. Interestingly, as a group, species with these CD4 characteristics all have high constituitive expression of class II molecules on T lymphocytes, suggesting potential uniqueness in the interaction of CD4, class II molecules, and the immune response. Molecular characterization of CD4 in an aquatic mammal provides information on the CD4 molecule itself and may provide insight into adaptive evolutionary changes of the immune system. Received: 1 July 1998 / Revised: 6 October 1998     

Evolutionary origin and diversification of the mammalian CD1 antigen genes.

CD1 antigens are cell-surface glycoproteins which have a molecular structure which is similar (consisting of extracellular domains alpha 1, alpha 2, and alpha 3, a transmembrane portion, and a cytoplasmic tail) to that of class I MHC molecules. Phylogenetic analysis of mammalian CD1 DNA sequences revealed that these genes are more closely related to the class I major histocompatibility complex (MHC) than to the class II MHC and that mammalian genes are more closely related to avian class I MHC genes than they are to mammalian class I MHC genes. The CD1 genes form a multigene family with different numbers of genes in different species (five in human, eight in rabbit, and two in mouse). Known CD1 genes are grouped into the following three families, on the basis of evolutionary relationship: (1) the human HCD1B gene and a partial sequence from the domestic rabbit, (2) the human HCD1A and HCD1C genes, and (3) the human HCD1D and HCD1E genes plus the two mouse genes and a sequence from the cottontail rabbit. The alpha 1 and alpha 2 domains of CD1 are much less conserved at the amino acid level than are the corresponding domains of class I MHC molecules, but the alpha 3 domain of CD1 seems to be still more conserved than the well-conserved alpha 3 domain of class I MHC molecules. Furthermore, in the human CD1 gene family, interlocus exon exchange has homogenized alpha 3 domains of all CD1 genes except HCD1C.     

Sequence and structural analysis of 4SNc-Tudor domain protein from Takifugu Rubripes

The fugu SN4TDR protein belongs to an evolutionarily conserved family, consisting of four repeat staphylococcal nuclease-like domains (SN1-SN4) at the N-terminus followed by Tudor and SN-like domains (TSN). Sequence analysis showed that the C-terminal TSN domain is composed of a complete SN-like domain interdigitated with a Tudor domain. In despite of low level of sequence identities, five SN-like domains have a few conserved amino acids that may play essential roles in the function of the protein. Computer modeling and secondary structural prediction of the SN-like domains revealed the presence of similar structural features of β1-β2-β3-α1-β4-β5-α2-α3, which provides a structural basis for oligonucleotides binding. The loop region L_3α for binding sites between β3 and α1 of SN-like domains are different from human p100, implying the divergence in the structures of binding sites. These results indicate that fugu SN4TDR may bind methylated ligands and/or oligonucleotides through its distant domains.     

Structure and domain organization of the CD19 antigen of human, mouse, and guinea pig B lymphocytes. Conservation of the extensive cytoplasmic domain.

The CD19 molecule is a 95,000 Mr cell-surface protein of human B lymphocytes with two extracellular Ig-like domains and a 240 amino acid cytoplasmic tail. cDNA encoding human CD19 and the cytoplasmic domain of the mouse CD19 Ag were previously isolated. In this report, those cDNA were used to isolate cDNA or genomic DNA encoding the complete mCD19 protein and a portion of CD19 from the guinea pig. Mouse pre-B and B cell lines expressed two CD19 mRNA species of 2.7 and 2.2 kb, whereas myeloma cell lines were negative as were T cell lines. Similarly, among mouse organs, only spleen contained detectable CD19 mRNA. These results suggest that only B cells express CD19 in mouse, as in man. Sequence determination revealed substantial conservation, with hCD19 and mCD19 being 66% and hCD19 and gpCD19 being 73% identical in amino acid sequence. The cytoplasmic region of CD19 was most highly conserved with human/mouse being 73% identical and human/guinea pig being 83% identical in amino acid sequence. Isolation of the hCD19 and mCD19 genes and determination of exon/intron boundaries revealed that both genes were structurally similar and were composed of at least 15 exons, 4 encoded extracellular domains, and 9 encoded cytoplasmic domains. Six of the exons that encoded cytoplasmic domains were essentially identical in sequence in all three species indicating that these regions have undergone considerable selective pressure to conserve sequences. Thus, CD19 appears to be well conserved in structure and expression through recent mammalian evolution and the highly conserved cytoplasmic domains may play a critical role in the transduction of CD19-mediated signals.     

Phosphorylation-dependent down-modulation of CD4 requires a specific structure within the cytoplasmic domain of CD4.

Several structural features of the cytoplasmic domain of CD4 including phosphorylation of Ser-408 have been shown to be important in its endocytosis (Shin, J., Doyle, C., Yang, Z., Kappes, D., and Strominger, J.L. (1990) EMBO J. 9, 425-434). A series of cytoplasmic domain truncations have now indicated that the membrane proximal region of the cytoplasmic domain from Arg-396 to Lys-417 is sufficient for phorbol ester-induced internalization; this segment is predicted to be an alpha-helix. The severe impairment of endocytosis resulting from the mutation Ser-408 to Ala-408 is largely restored by a compensating mutation Ala-404 to Ser-404; phosphorylation of Ser-404 has been directly demonstrated. Furthermore, mutation of Met-407, Ile-410, Leu-413, or Leu-414 to a hydrophilic residue eliminated CD4 endocytosis as did domain truncation at Arg-412. Ser-408 was normally phosphorylated in all of these mutants, suggesting that other residues in this region, including the four hydrophobic amino acids, are also required for CD4 endocytosis. Immunofluorescence microscopy following staining of intact and permeabilized cells showed that all endocytosis defective mutants indeed remained on the cell surface even after phorbol ester treatment, while wild type CD4 was endocytosed and degraded in lysosomes. These data indicate that endocytosis requiring residues 397-417 and binding of lymphocyte tyrosine kinase at residues 417-429 are functions of independent segments of the cytoplasmic region and lead to a hypothesis regarding some features of the endocytic process.     

CD4 homologues in Atlantic salmon

In mammals CD4 is a membrane glycoprotein on Th cells with four extracellular immunoglobulin-like (Ig-like) domains (D1-D4). It functions as a co-receptor during immune recognition between the TCR and the MHC II/peptide complex. The cytoplasmic domain binds p56lck, a protein kinase responsible for phosphorylating CD3 which is the first interaction in a cascade leading to T cell activation. We have previously reported a CD4-2 gene in rainbow trout (Oncorhynchus mykiss) which was found adjacent to the CD4-1 gene by synteny analysis. There are two subtypes (a and b) of CD4-2 in rainbow trout, with two Ig-like extracellular domains. Here we present the homologues of mammalian CD4 in Atlantic salmon (Salmo salar): CD4-1 with four extracellular domains and CD4-2a and CD4-2b with two extracellular domains. A Southern blot analysis shows two copies of the CD4-1 gene in the genomic DNA of the closely related rainbow trout. The genes for CD4-1 and CD4-2 have been sequenced and show typical traits for CD4 genes, such as the code for the first domain (D1) being divided between two exons and the other domains being largely coded for by single exons. The corresponding translated cDNAs show little (13-17%) identity to higher vertebrates and are approximately 37% similar to other translated, teleost sequences but are 89% identical to the closely related rainbow trout. However they exhibit conserved features such as the Lck binding motif in their cytoplasmic domains and the order of variable and constant type Ig-like domains. qRT-PCR data are presented describing the differential tissue expression of these genes together with other T cell markers (TCR and CD3) in several individuals.     

The CD8alpha from sea bass (Dicentrarchus labrax L.): Cloning, expression and 3D modelling

In this paper we describe the cloning, expression and structural study by modelling techniques of the CD8alpha from sea bass (Dicentrarchus labrax L.). The sea bass CD8alpha cDNA is comprised of 1490 bp and is translated in one reading frame to give a protein of 217 amino acids, with a predicted 26 amino acids signal peptide, a 88 bp 5'-UTR and a 748 bp 3'-UTR. A multiple alignment of CD8alpha from sea bass with other known CD8alpha sequences shows the conservation of most amino acid residues involved in the peculiar structural domains found within CD8alpha's. Cysteine residues that are involved in disulfide bonding to form the V domain are conserved. In contrast, an extra cysteine residue found in most mammals in this region is not present in sea bass. The transmembrane and cytoplasmic regions are the most conserved regions within the molecule in the alignment analysis. However, the motif (CXCP) that is thought to be responsible for binding p56lck is missing in the sea bass sequence. Phylogenetic analysis conducted using amino acid sequences showed that sea bass CD8alpha grouped with other known teleost sequences and that three different clusters were formed by the mammalian, avian and fish CD8alpha sequences. The thymus was the tissue with the highest CD8alpha expression, followed by gut, gills, peripheral blood leukocytes and spleen. Lower CD8alpha mRNA levels were found in head kidney, liver and brain. It was possible to create a partial 3D model using the human and mouse structures as template. The CD8alpha 11-120 amino acid region was taken into consideration and the best obtained 3D model shows the presence of ten beta-strands, involving about 50% of the sequence. The global structure was defined as an immunoglobulin-like beta-sandwich made of two anti-parallel sheets. Two cysteines were present in this region and they were at a suitable distance to form an S-S bond as seen in the template human and mouse structures.     

Cloning and modeling of the first nonmammalian CD4

We have cloned and sequenced the first nonmammalian CD4 cDNA from the chicken using the COS cell expression method. Chicken CD4 contains four extracellular Ig domains that, in analogy to mammalian CD4, are in the order V, C2, V, and C2. The molecule is 24% identical with both human and mouse sequences. The extracellular domains were modeled using human and rat CD4 crystal structures as templates. In the first domain there are two extra Cys residues that are at suitable distance to form an intra-beta-sheet disulfide bridge in addition to the canonical one in the V domain. The region responsible for the interaction with MHC class II is relatively nonconserved in chicken. However, there are positively charged amino acids in the C" region of the N-terminal domain that may mediate the association to the negatively charged residues of the MHC class II beta-chain. Molecular modeling also implies that the membrane-proximal domain mediates dimerization of chicken CD4 in a similar way as it does for human CD4. Furthermore, the cytoplasmic tail is highly conserved, containing the protein tyrosine kinase p56lck recognition site that is preceded by an adjacent di-leucine motif for the internalization of the molecule. Interestingly, there are no Ser residues in the cytoplasmic part, which may explain the slow down-regulation of chicken CD4 after phorbol ester stimulation.     

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.     

Molecular Cloning and Chromosomal Localization of the MouseGpr37Gene Encoding an Orphan G-Protein-Coupled Peptide Receptor Expressed in Brain and Testis

We report the cloning of the mouse ortholog of the humanGPR37gene, which encodes an orphan G-protein-coupled receptor highly expressed in brain tissues and homologous to neuropeptide-specific receptors ([20],Genomics 45:68–77;[45],Biochem. Biophys. Res. Commun. 233:559–567). The genomic organization of theGPR37gene is conserved in both mouse and human species with a single intron interrupting the receptor-coding sequence within the presumed third transmembrane domain. Comparative genetic mapping of theGPR37gene showed that it maps to a conserved chromosomal segment on proximal mouse chromosome 6 and human chromosome 7q31. The mouseGpr37gene contains an open reading frame coding for a 600-amino-acid protein 83% identical to the humanGPR37gene product. The predicted mouse GPR37 protein contains seven putative hydrophobic transmembrane domains, as well as a long (249 amino acid residues), arginine- and proline-rich amino-terminal extracellular domain, which is also a distinctive feature of the human GPR37 receptor. Northern blot analysis of mouse tissues withGpr37-specific probes revealed a main 3.8-kb mRNA and a much less abundant 8-kb mRNA, both expressed in the brain. A 3-kb mRNA is also expressed in the testis. Both the mouse and the humanGPR37genes may belong to a class of highly conserved mammalian genes encoding a novel type of G-protein-coupled receptor predominantly expressed in the brain.