The EGF-TM7 family: a postgenomic view

With the human and mouse genome projects now completed, the receptor repertoire of mammalian cells has finally been elucidated. The EGF-TM7 receptors are a family of class B seven-span transmembrane (TM7) receptors predominantly expressed by cells of the immune system. Within the large TM7 superfamily, the molecular structure and ligand-binding properties of EGF-TM7 receptors are unique. Derived from the processing of a single polypeptide, they are expressed at the cell surface as heterodimers consisting of a large extracellular region associated with a TM7 moiety. Through a variable number of N-terminal epidermal growth factor (EGF)-like domains, EGF-TM7 receptors interact with cellular ligands such as CD55 and chondroitin sulfate. Recent in vivo studies demonstrate a role of the EGF-TM7 receptor CD97 in leukocyte migration. The different number of EGF-TM7 genes in man compared with mice, the chimeric nature of EMR2 and the inactivation of human EMR4 point toward a still-evolving receptor family. Here we discuss the currently available information on this intriguing receptor family.     

Identification of three alternatively spliced variants of human CD28 mRNA.

CD28, expressed by T cells, plays a central role in providing costimulatory signals to T cells. The cd28 gene is organized into 4 exons. An alternatively spliced CD28 mRNA lacking most of the exon 2 has been previously evidenced. We report here that non stimulated human T cells express three additional alternatively spliced variants of CD28 mRNA (CD28a-c) in. The CD28a variant, expressed at similar levels to that of the full length CD28 mRNA encoding for the membrane form, lacks exon 3. This deletion introduces (i) a frame shift resulting in the addition of two extra amino acids and a premature stop codon and, (ii) induces the loss of the transmembrane region, suggesting that it could encodes for a soluble monomeric molecule which conserves the binding sites of CD28. The CD28b and CD28c variants, expressed at a low level compared with CD28a, are generated by deletion of most of the 3' end of exon 2 plus exon 3 and exon 2 plus exon 3, respectively. Activated T cells express only the membrane CD28 mRNA. These results suggest that resting human T cells may constitutively express both membrane and soluble CD28 which can differentially regulate the outcome of the T cell response.     

TM7XN1, a novel human EGF-TM7-like cDNA, detected with mRNA differential display using human melanoma cell lines with different metastatic potential

We have identified a novel 3845 bp cDNA differentially expressed in a human melanoma metastasis model. Northern blot analysis showed expression in the poorly and intermediately metastasizing cell lines and a marked downregulation in the highly metastatic cell lines. Using RT-PCR expression was also seen in several other tumor cell lines and normal cell types of human origin. cDNA sequence analysis revealed an ORF of 687 amino acids containing seven putative transmembrane domains C-terminally and a long N-terminus. The gene was mapped to 16q13. Highest homology was observed with members of the EGF-TM7 subfamily of the secretin/calcitonin receptor family. We propose the delineation of a subfamily of TM7 proteins, LN-TM7, containing seven transmembrane proteins with a long N-terminal extracellular part.     

Identification and characterization of five-transmembrane isoforms of human vasoactive intestinal peptide and pituitary adenylate cyclase-activating polypeptide receptors

The seven-transmembrane (7TM) G-protein-coupled neuroendocrine receptors VPAC1 (HGNC approved gene symbol VIPR1) and VPAC2 (HGNC approved gene symbol VIPR2) are expressed in different tissues and involved in the regulation of important biological functions. We now report the identification and characterization of novel five-transmembrane(5TM) forms of both human VPAC1 and human VPAC2. These alternatively spliced variant mRNAs result from the skipping of exons 10/11, spanning the third intracellular loop, the fourth extracellular loop, and the transmembrane regions 6 and 7, producing in-frame 5TM receptors predicted to lack a G-protein-binding motif. RT-PCR showed that these 5TM receptors are differentially expressed in transformed and normal cells. Translation of the 5TM protein was demonstrated by transfection and expression in CHO cells. Following agonist stimulation, differential signaling of the 7TM versus 5TM forms was shown both for the activation of adenylate cyclase and for tyrosine phosphorylation. The identification of these splice variants in various cells and their expression and differential signal transduction compared to the 7TM form suggest that these novel receptors have biological relevance.     

Human epidermal growth factor (EGF) module-containing mucin-like hormone receptor 3 is a new member of the EGF-TM7 family that recognizes a ligand on human macrophages and activated neutrophils

The epidermal growth factor (EGF)-TM7 subgroup of G-protein-coupled receptors is composed predominantly of leukocyte-restricted glycoproteins defined by their unique hybrid structure, in which extracellular EGF-like domains are coupled to a seven-span transmembrane moiety via a mucin-like stalk. The EGF-TM7 group comprises mouse F4/80, human EGF module-containing mucin-like hormone receptor (EMR) 1, human EMR2, and human and mouse CD97, the genes for which map to human chromosome 19p13 and the syntenic regions of the mouse genome. In this study we describe the cloning and characterization of EMR3, a novel human EGF-TM7 molecule, and show the existence of its cellular ligand. The EMR3 gene maps closely to the existing members of the EGF-TM7 family on human chromosome 19p13.1 and, in common with other EGF-TM7 genes, is capable of generating different protein isoforms through alternative splicing. Two alternative splice forms have been isolated: one encoding a 652-amino acid cell surface protein consisting of two EGF-like domains, a mucin stalk, and a putative G-protein-coupled receptor domain and the other encoding a truncated soluble form containing only two EGF-like domains. As with other members of the EGF-TM7 family, EMR3 mRNA displays a predominantly leukocyte-restricted expression pattern, with highest levels in neutrophils, monocytes, and macrophages. Through the use of soluble EMR3 multivalent probes we have shown the presence of a ligand at the surface of monocyte-derived macrophages and activated human neutrophils. These interactions suggest a potential role for EMR3 in myeloid-myeloid interactions during immune and inflammatory responses.     

The role of receptor oligomerization in modulating the expression and function of leukocyte adhesion-G protein-coupled receptors

The human leukocyte adhesion-G protein-coupled receptors (GPCRs), the epidermal growth factor (EGF)-TM7 proteins, are shown here to function as homo- and hetero-oligomers. Using cell surface cross-linking, co-immunoprecipitation, and fluorescence resonance energy transfer analysis of EMR2, an EGF-TM7 receptor predominantly expressed in myeloid cells, we demonstrate that it forms dimers in a reaction mediated exclusively by the TM7 moiety. We have also identified a naturally occurring but structurally unstable EMR2 splice variant that acts as a dominant negative modulator by dimerizing with the wild type receptor and down-regulating its expression. Additionally, heterodimerization between closely related EGF-TM7 members is shown to result in the modulation of expression and ligand binding properties of the receptors. These findings suggest that receptor homo- and hetero-oligomerization play a regulatory role in modulating the expression and function of leukocyte adhesion-GPCRs.     

Alternative splicing of human synexin mRNA in brain, cardiac, and skeletal muscle alters the unique N-terminal domain.

Several synexin (annexin VII) mRNAs have been identified by screening a human fibroblast cDNA library. One type of message contained an alternatively spliced cassette exon, predicting two isoforms of synexin differing in the N-terminal domain. Polymerase chain reaction analysis of synexin mRNA from various fetal and adult tissues, from human and monkey, revealed that the alternative splicing event is tissue-regulated; synexin mRNA containing the cassette exon is prevalent in brain, heart, and skeletal muscle. This is supported by Western blot analysis showing that muscle synexin (annexin VIIb) is larger than synexin from lung (annexin VIIa). The muscle and lung isoforms have the same molecular mass as the recombinant synexins expressed in Escherichia coli using cDNAs containing or lacking the cassette exon, respectively. The difference in size is consistent with the molecular masses predicted from the proteins encoded by the alternatively spliced synexin mRNAs. Another type of synexin mRNA contained a longer 3'-noncoding region generated by the selection of an alternate poly(A) signal. Northern analysis of human fibroblast RNA showed the presence of two bands (2.0- and 2.4-kilobase) when hybridized to a cDNA fragment of the coding region of synexin, but only the 2.4-kilobase band hybridized to a probe made from the longer 3' end.