A striking organization of a large family of human neural cadherin-like cell adhesion genes.

We have identified 52 novel human cadherin-like genes organized into three closely linked clusters. Comparison of the genomic DNA sequences with those of representative cDNAs reveals a striking genomic organization similar to that of immunoglobulin and T cell receptor gene clusters. The N-terminal extracellular and transmembrane domains of each cadherin protein are encoded by a distinct and unusually large exon. These exons are organized in a tandem array. By contrast, the C-terminal cytoplasmic domain of each protein is identical and is encoded by three small exons located downstream from the cluster of N-terminal exons. This unusual organization has interesting implications regarding the molecular code required to establish complex networks of neuronal connections in the brain and the mechanisms of cell-specific cadherin-like gene expression.     

Myelin Po-protein,more than just a structural protein?

The protein P0 has long been proposed to be responsible for the compact nature of peripheral myelin through interactions of both its extracellular and cytoplasmic domains. Recent studies support such a role for P0's extracellular region while more precise mapping of its adhesive domains are ongoing. As P0 is a member of the immunoglobulin gene superfamily and perhaps bears the closest similarity to the ancestral molecule of this whole family, these studies may also have more general implications for adhesive interactions. In addition, although long believed to be purely an inert, structural molecule, P0 has been reported to promote neurite outgrowth, which suggests a more dynamic role for this interesting molecule.     

Isolation and sequence of a cDNA encoding the major structural protein of peripheral myelin

The myelin sheath is a multilayered membrane, unique to the nervous system, which functions as an insulator to increase greatly the velocity of axonal impulse conduction. We have used the techniques of differential screening and hybrid selection to identify a cDNA clone encoding the Schwann cell glycoprotein P0, the major structural protein of the peripheral myelin sheath. The sequence of this protein, deduced from the nucleotide sequence of the cloned cDNA, indicates that P0 is an integral membrane protein containing a single membrane-spanning region, a large hydrophobic extracellular domain, and a smaller basic intracellular domain. The structure of the protein suggests that each of these domains plays an essential role in generating the highly ordered structure of the myelin sheath. Furthermore, we find that the induction of P0 mRNA coincides with the initiation of myelin formation, and we propose a model in which the glycoprotein serves as a molecular guidepost for this process.     

Protein zero of peripheral nerve myelin: biosynthesis, membrane insertion, and evidence for homotypic interaction.

Protein zero (P0), an integral membrane glycoprotein synthesized by Schwann cells, is the major glycoprotein of peripheral nerve myelin. The predicted disposition of P0 with respect to the membrane bilayer postulates the existence of extracellular and intracellular domains, that mediate compaction of the myelin lamellae. We used in vitro translations programmed with sciatic nerve mRNA and cells transfected with a P0 cDNA construct to study the biosynthesis and topology of P0 in the bilayer. The behavior of P0 at the cell surface, when expressed under physiological conditions, was also examined. We have verified the topological predictions of an earlier model, derived from analysis of a P0 cDNA, and provide evidence that the extracellular domain of P0 mediates homotypically cell-cell interactions in the transfectants.     

The analysis of genomic structures in the L1 family of cell adhesion molecules provides no evidence for exon shuffling events after the separation of arthropod and chordate lineages

Members of the L1 family of neural cell adhesion molecules consist of multiple extracellular immunoglobulin and fibronectin type III domains that mediate the adhesive properties of this group of transmembrane proteins. In vertebrate genomes, these protein domains are separated by introns, and it has been suggested that L1-type genes might have been subject to exon-shuffling events during evolution. However, comparison of the human L1-CAM and the chicken neurofascin gene with the genomic structure of their Drosophila homologue, neuroglian, indicates that no major rearrangement of protein domains has taken place subsequent to the split of the arthropod and chordate phyla. The Drosophila neuroglian gene appears to have lost most of the introns that have been conserved in the human L1-CAM and the chicken neurofascin gene. Nevertheless, exon shuffling or the generation of new exons by mutational changes might have been responsible for the generation of additional, alternatively spliced exons in L1-type genes.     

Expression and Purification of the Extracellular Domain of Human Myelin Protein Zero

Myelin protein zero (P0), an adhesion protein of the immunoglobulin superfamily, is the major protein of peripheral nervous system myelin in higher vertebrates. Protein zero is required for the formation and maintenance of myelin structure in the internode, likely through homophilic interactions at both the extracellular and the intracellular domains. Mutations and deletions in the P0 gene correlate with hereditary peripheral neuropathies of varying severity. Comparisons between the human and rat isoforms, whose three-dimensional structure has been determined by X-ray crystallography, suggest that these disease-associated genetic alterations lead to structural changes in the protein that alter P0-P0 interactions and hence affect myelin functionality. Knowing the crystal structures of native and altered human P0 isoforms could help to elucidate the structural changes in myelin membrane packing that underlie the altered functionality. Alterations of P0 extracellular domain (P0-ED) are of additional interest as previous X-ray diffraction studies on myelin membrane packing suggest that P0-ED molecules can assume distinct adhesive arrangements. Here, we describe an improved method to express and purify human P0-ED (hP0-ED) suitable for crystallographic analysis. A fusion protein consisting of maltose binding protein fused to hP0-ED was secreted to the periplasm of Escherichia coli to allow an appropriate folding pathway. The fusion protein was extracted via osmotic shock and purified by affinity chromatography. Factor Xa was used to cleave the fusion protein, and a combination of affinity and ion-exchange chromatography was used to further purify hP0-ED. We document several significant improvements to previous protocols, including bacterial growth to approximately 15 OD using orbital shakers and the use of diafiltration, which result in yields of approximately 150 mg highly pure protein per liter of medium.     

Schwann cell myelination requires timely and precise targeting of P(0) protein

This report investigated mechanisms responsible for failed Schwann cell myelination in mice that overexpress P(0) (P(0)(tg)), the major structural protein of PNS myelin. Quantitative ultrastructural immunocytochemistry established that P(0) protein was mistargeted to abaxonal, periaxonal, and mesaxon membranes in P(0)(tg) Schwann cells with arrested myelination. The extracellular leaflets of P(0)-containing mesaxon membranes were closely apposed with periodicities of compact myelin. The myelin-associated glycoprotein was appropriately sorted in the Golgi apparatus and targeted to periaxonal membranes. In adult mice, occasional Schwann cells myelinated axons possibly with the aid of endocytic removal of mistargeted P(0). These results indicate that P(0) gene multiplication causes P(0) mistargeting to mesaxon membranes, and through obligate P(0) homophilic adhesion, renders these dynamic membranes inert and halts myelination.     

The gene of the neural cell recognition molecule F11: conserved exon-intron arrangement in genes of neural members of the immunoglobulin superfamily

The chicken neural glycoprotein F11 is a cell recognition molecule implicated in neurohistogenesis, in particular in the context of neurite outgrowth and fasciculation. F11 is a glycosyl-phosphatidylinositol-linked member of the immunoglobulin superfamily that is also termed contactin or F3 in humans and rodents, respectively. In this study, we report the complete structure of the F11 gene. It is composed of 23 exons distributed over more than 100 kb of genomic DNA and each of the ten domains of the F11 protein is encoded by two exons. The sizes of the introns vary by two orders of magnitude ranging from 150 bp to more than 15 kb. All interdomain introns are in phase one, i.e. are inserted after the first nucleotide of a codon, being consistent with assembly of a F11 progenitor gene via exon shuffling. The intradomain introns are localized at variable sites within the domains and have different intron phases. This study reveals a remarkable similarity of the F11 gene with the gene of axonin-1, a related neural immunoglobulin superfamily member which is also implicated in neurite outgrowth and fasciculation. The intron positions with respect to the protein domain organization are found to be identical, strongly suggesting that both genes are derived from a common ancestor that already had this exon-intron structure.     

Evolution of the human killer cell inhibitory receptor family

Phylogenetic analysis of different domains of human natural killer cell inhibitory receptors (KIR) implicated both intragenic duplication and deletion of exons and interlocus recombination in the evolution of these receptors. In phylogenies of the extracellular immunoglobulin (Ig) superfamily C2-set domains and of the pre-membrane (PM) domain, KIR receptors having two C2-set domains and those having three such domains tended to form separate clusters. However, the phylogenies of the transmembrane (TM) and cytoplasmic (CYT) domains showed quite different topologies, suggesting that major sites of interlocus recombination have been between exon 6 (encoding PM) and exon 7 (encoding TM) and between exon 7 and exons 8-9 (encoding CYT). Examination of the pattern of nucleotide substitution in the exons encoding Ig C2-set domains supported the hypothesis that positive Darwinian selection has acted to diversify the residues within these domains that are involved in contact with class I MHC molecules.     

Gene structure of chick cartilage chondroitin sulfate proteoglycan (aggrecan) core protein

Large aggregating chondroitin sulfate proteoglycan (CSPG/aggrecan) is one of the major extracellular matrix components in cartilage. The core protein is also large, over 200 kDa, and modular with a distinct correspondence between protein structural domains and the encoding exons. Here we report the isolation, using chick CSPG cDNA probes and the ensuing sequencing, of genomic clones containing exons encoding the chick CSPG core protein. The 5 two globular domains, G1 and G2, are encoded by four and three exons, respectively, and the interglobular domain is encoded by a single exon. The chondroitin sulfate attachment domain is encoded by the largest exon, 3,216 bp, which is approximately 50% of the total coding sequence. Combined with the previous report (Tanaka, T., Har-el, R. Tanzer, M.L. 1988 J. Biol. Chem. 263, 15831–15835), these data reveal that the chick CSPG gene contains at least 18 exons spanning a genome which is greater than 30 kb. No evidence was obtained for multiple genes for aggrecan in the chick genome. Elucidation of the chick genomic structure allows comparison of the avian and mammalian link protein genes to the homologous portions of avian and mammalian core protein genes (hyaluronate binding domain) with respect to their origins and paths of duplication and divergence. Correspondence to: N.B. Schwartz     

Characterization and comparative structural features of the gene for human interstitial retinol-binding protein

We have cloned the gene for human interstitial retinol-binding protein (IRBP) and compared its nucleotide sequence with that of the corresponding cloned cDNA. The human IRBP gene is approximately 9.5 kilobase pairs (kbp) in length and consists of four exons separated by three introns. The introns are 1.6-1.9 kbp long. The gene is transcribed by photoreceptor and retinoblastoma cells into an approximately 4.3-kilobase mRNA that is translated and processed into a glycosylated protein of 135,000 Da. The amino acid sequence of human IRBP can be divided into four contiguous homology domains with 33-38% identity, suggesting a series of gene duplication events. In the gene, the boundaries of these domains are not defined by exon-intron junctions, as might have been expected. The first three homology domains and part of the fourth are all encoded by the first large exon, which is 3,180 base pairs long. The remainder of the fourth domain is encoded in the last three exons, which are 191, 143, and approximately 740 base pairs long, respectively. This unusual structure is shared with the bovine IRBP gene. A large (1.7 kbp) fragment appears to have been lost from the 3'-noncoding region of the last human exon. We conclude that the human and bovine genes have similar evolutionary histories.     

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 cytoplasmic domain of the myelin P0 protein influences the adhesive interactions of its extracellular domain

The extracellular domain of the myelin P0 protein is believed to engage in adhesive interactions and thus hold the myelin membrane compact. We have previously shown that P0 can behave as a homophilic adhesion molecule through interactions of its extracellular domains (Filbin, M. T., F. S. Walsh, B. D. Trapp, J. A. Pizzey, and G. I. Tennekoon. 1990. Nature (Lond.) 344:871-872). To determine if the cytoplasmic domain of P0 must be intact for the extracellular domains to adhere, we compared the adhesive capabilities of P0 proteins truncated at the COOH-terminal to the full-length P0 protein. P0 cDNAs lacking nucleotides coding for the last 52 or 59 amino acids were transfected into CHO cells, and surface expression of the truncated proteins was assessed by immunofluorescence, surface labeling followed by immunoprecipitation, and an ELISA. Cell lines were chosen that expressed at least equivalent amounts of the truncated P0 proteins at the surface as did a cell line expressing the full-length P0. The adhesive properties of these three cell lines were compared. It was found that when a suspension of single cells was allowed to aggregate for a period of 60 min, only the cells expressing the full-length P0 had formed large aggregates, while the cells expressing the truncated P0 molecules were still mostly single cells indistinguishable from the control cells. Furthermore, 25-30% of the full-length P0 was insoluble in NP40, indicative of an interaction with the cytoskeleton, whereas only 5-10% of P0 lacking 52 amino acids and none of P0 lacking 59 amino acids were insoluble. These results suggest that for the extracellular domain of P0 to behave as a homophilic adhesion molecule, its cytoplasmic domain must be intact, and most probably, it is interacting with the cytoskeleton.     

The amino acid sequences of the myelin-associated glycoproteins: homology to the immunoglobulin gene superfamily

The myelin associated glycoproteins (MAG) are integral plasma membrane proteins which are found in oligodendrocytes and Schwann cells and are believed to mediate the axonal-glial interactions of myelination. In this paper we demonstrate the existence in central nervous system myelin of two MAG polypeptides with Mrs of 67,000 and 72,000 that we have designated small MAG (S-MAG) and large MAG (L-MAG), respectively. The complete amino acid sequence of L-MAG and a partial amino acid sequence of S-MAG have been deduced from the nucleotide sequences of corresponding cDNA clones isolated from a lambda gt11 rat brain expression library. Based on their amino acid sequences, we predict that both proteins have an identical membrane spanning segment and a large extracellular domain. The putative extracellular region contains an Arg-Gly-Asp sequence that may be involved in the interaction of these proteins with the axon. The extracellular portion of L-MAG also contains five segments of internal homology that resemble immunoglobulin domains, and are strikingly homologous to similar domains of the neural cell adhesion molecule and other members of the immunoglobulin gene superfamily. In addition, the two MAG proteins differ in the extent of their cytoplasmically disposed segments and appear to be the products of alternatively spliced mRNAs. Of considerable interest is the finding that the cytoplasmic domain of L-MAG, but not of S-MAG, contains an amino acid sequence that resembles the autophosphorylation site of the epidermal growth factor receptor.