The fourth immunoglobulin-like domain of NCAM contains a carbohydrate recognition domain for oligomannosidic glycans implicated in association with L1 and neurite outgrowth.

We have previously shown that the neural adhesion molecules L1 and NCAM interact with each other to form a complex which binds more avidly to L1 than L1 to L1 alone (Kadmon, G., A. Kowitz, P. Altevogt, and M. Schachner. 1990a. J. Cell Biol. 110:193-208). This cis-association between L1 and NCAM is carbohydrate-dependent (Kadmon, G., A. Kowitz, P. Altevogt, and M. Schachner. 1990b. J. Cell Biol. 110:209-218). In the present study, we report that L1 and NCAM bind to each other via oligomannosidic carbohydrates expressed by L1, but not by NCAM, as shown in several experiments: (a) complex formation between L1 and NCAM is inhibited by a mAb to oligomannosidic carbohydrates and by the oligosaccharides themselves; (b) NCAM binds to oligomannosidic carbohydrates; (c) within the L1/NCAM complex, the oligomannosidic carbohydrates are hidden from accessibility to a mAb against oligomannosidic carbohydrates; (d) the recombinant protein fragment of NCAM containing the immunoglobulin-like domains and not the fragment containing the fibronectin type III homologous repeats binds to oligomannosidic glycans. Furthermore, the fourth immunoglobulin-like domain of NCAM shows sequence homology with carbohydrate recognition domains of animal C-type lectins and, surprisingly, also with plant lectins. A peptide comprising part of the C-type lectin consensus sequence in the fourth immunoglobulin-like domain of NCAM interferes with the association between L1 and NCAM. The functional importance of oligomannosidic glycans at the cell surface was shown for neurite outgrowth in vitro. When neurons from early postnatal mouse cerebellum were maintained on laminin or poly-L-lysine, neurite outgrowth was inhibited by oligomannosidic glycans, by glycopeptides, glycoproteins, or neoglycolipids containing oligomannosidic glycans, but not by nonrelated oligosaccharides or oligosaccharide derivates. Neurite outgrowth was also inhibited by the peptide comprising part of the C-type lectin consensus sequence in the fourth immunoglobulin-like domain of NCAM. The combined results suggest that carbohydrate-mediated cis-associations between adhesion molecules at the cell surface modulate their functional properties.

Degeneration of neural cells in the central nervous system of mice deficient in the gene for the adhesion molecule on Glia, the beta 2 subunit of murine Na,K-ATPase.

We generated mice, null mutant in the adhesion molecule on glia (AMOG), the beta 2 subunit of the murine Na,K-ATPase gene. These mice exhibit motor incoordination at 15 d of age, subsequently tremor and paralysis of extremities, and die at 17-18 d after birth. At these ages, the mutants have enlarged ventricles, degenerating photoreceptor cells, and swelling and degeneration of astrocytic endfeet, leading to vacuoles adjoining capillaries of brain stem, thalamus, striatum, and spinal cord. In tissue homogenates from entire brains of 16-17-d-old mutants, Na,K-ATPase activity and expression of the beta 1 subunit of the Na,K-ATPase and of the neural adhesion molecules L1, N-CAM, and MAG appear normal. We suggest that the mutant phenotype can be related primarily to reduced pump activity, with neural degeneration as a possible consequence of osmotic imbalance.

A transgenic rat model of Charcot-Marie-Tooth disease.

Charcot-Marie-Tooth disease (CMT) is the most common inherited neuropathy in humans and has been associated with a partial duplication of chromosome 17 (CMT type 1A). We have generated a transgenic rat model of this disease and provide experimental evidence that CMT1A is caused by increased expression of the gene for peripheral myelin protein-22 (PMP22, gas-3). PMP22-transgenic rats develop gait abnormalities caused by a peripheral hypomyelination, Schwann cell hypertrophy (onion bulb formation), and muscle weakness. Reduced nerve conduction velocities closely resemble recordings in human patients with CMT1A. When bred to homozygosity, transgenic animals completely fail to elaborate myelin. We anticipate that the CMT rat model will facilitate the identification of a cellular disease mechanism and serve in the evaluation of potential treatment strategies.

Efficient gene delivery into adult cardiomyocytes by recombinant Sindbis virus.

Somatic gene therapy as a potential strategy for the treatment of myocardial diseases relies on an efficient gene transfer into cardiac muscle cells. The difficulty of delivering genes into adult cardiomyocytes exists not only in vivo but also in primary culture systems. Therefore, possibilities for ex vivo gene transfer and the in vitro study of physiological processes by reverse genetics are limited. We investigated the potential of an alphavirus-based vector system to transduce adult rat cardiomyocytes (ARC) in culture using a replication-deficient Sindbis virus (SIN) encoding beta-galactosidase (SIN-LacZ). Transduction efficiency depended on the virus concentration used, with expression of the reporter gene being detectable in up to 80% of cultured ARC as early as 24 h after infection. We observed a remarkably lower cytotoxicity of this viral vector in ARC than in other cells such as fibroblasts and neonatal cardiomyocytes. Additionally, no perceptible changes in the morphology of the nuclei or cytoskeleton were found in ARC 48 h after infection with SIN-LacZ. We conclude that SIN vectors are useful for gene delivery into adult cardiomyocytes and believe that improved versions of this viral system may be useful for cardiovascular gene therapy in the future.

Myelin and lymphocyte protein (MAL/MVP17/VIP17) and plasmolipin are members of an extended gene family.

An increasing number of four-transmembrane proteins has been found to be associated with CNS and PNS myelin. Some of these proteins play crucial roles in the development and maintenance of the nervous system. In the CNS, proteolipid protein (PLP) is mutated in the myelin disorder Pelizaeus-Merzbacher disease and in spastic paraplegia, while in the PNS, peripheral myelin protein 22 (PMP22) and connexin32 (C x 32) are culprit genes in the most frequent forms of hereditary peripheral neuropathies. Myelin and lymphocyte protein (MAL; also called MVP17 or VIP17) and plasmolipin are additional tetraspan proteins that are highly expressed by myelinating glial cells. However, little is known about the role of these proteins in the nervous system. As a prerequisite for functional genetic approaches in the mouse, we have isolated and characterized a mouse MAL cDNA and the corresponding structural MAL gene. Computer-aided analysis and database searches revealed that MAL belongs to a larger gene family which also includes plasmolipin, BENE and the expressed sequence tag (EST) H09290. While the overall amino acid sequence identities between mouse MAL and the related proteins are relatively low (29-37%), the conserved motif -[Q/Y-G-W-V-M-F/Y-V]- which is found at the junction of the first extracellular loop and the second membrane-associated domain serves as a fingerprint for the MAL protein family. Expression analysis of the members of the MAL gene family indicates widespread expression in various tissues, suggesting a common role of these proteins in cell biology.

Mass production of embryoid bodies in microbeads.

Embryonic stem cells (ESC) are totipotent cells that can differentiate into a large number of different cell types. Stem cell-derived, differentiated cells are of increasing importance as a potential source for non-proliferating cells (e.g., cardiomyocytes or neurons) for future tissue engineering applications. Differentiation of ESC is initiated by the formation of embryoid bodies (EB). Current protocols for the generation of EB are either of limited productivity or deliver EB with a large variation in size and differentiation state. To establish an efficient and robust EB production process, we encapsulated mouse ESC into alginate microbeads using various microencapsulation technologies. Microencapsulation and culturing of ESC in 1.1% alginate microbeads gives rise to discoid colonies, which further differentiate within the beads to cystic EB and later to EB containing spontaneously beating areas. However, if ESC are encapsulated into 1.6% alginate microbeads, differentiation is inhibited at the morula-like stage, so that no cystic EB can be formed within the beads. ESC colonies, which are released from 1.6% alginate microbeads, can further differentiate to cystic EB with beating cardiomyocytes. Extended supplementation of the growth medium with retinoic acid promotes differentiation to smooth muscle cells.

Molecular approaches towards the isolation of tyrosine phosphatases expressed in the peripheral nervous system.

Protein tyrosine phosphatases (PTP) are increasingly appreciated to play a crucial function in the development, homeostasis and regeneration of the nervous system. In an attempt to determine the set of PTPs that are expressed in the PNS, we have employed polymerase chain reaction (PCR)-based strategies. Degenerate oligonucleotide primers which were designed based on PTP-consensus motifs were used on substrate cDNAs derived from sciatic nerves of either 3, 10 or 60 days-old rats as well as from cultured rat Schwann cells. The resulting partial PTP clones were used for low-stringency hybridization screening of a cDNA library constructed from the sciatic nerves of 7 to 8 days-old rats. The combined approaches yielded three known rat PTPs and at least three potential rat species homologues of previously identified mouse PTPs. Furthermore, several partial clones encoding potentially novel PTPs have been isolated. The suitability of our experimental approaches for the identification and characterization of PNS-expressed PTPs will be discussed.

Distal axonopathy in peripheral nerves of PMP22-mutant mice.

A partial duplication of chromosome 17 is associated with Charcot-Marie-Tooth disease type 1A (CMT1A), a demyelinating peripheral neuropathy that causes progressive distal muscle atrophy and sensory impairment. Trisomic expression of peripheral myelin protein 22 (PMP22) whose gene is contained within the duplicated region is considered to be responsible for the disease. By using recombinant gene technology in rodents, we had demonstrated previously that PMP22 is sensitive to gene dosage. Homozygous PMP22 knockout (PMP22(0/0)) mice and transgenic animals carrying additional copies of the PMP22 gene develop distinct peripheral polyneuropathies. We have now performed a detailed morphometrical analysis of the L3 roots, quadriceps and saphenous nerves of these PMP22-mutant mice to study whether the myelin and potential axonal deficits are evenly distributed. The L3 roots and the peripheral nerves were chosen as representatives of the proximal and distal segments of the peripheral nervous system. When the roots were compared with the peripheral nerves, myelin deficiencies appeared more severe at the radicular levels, in particular the ventral roots. Decreased numbers of large calibre axons were a prominent feature in the motor branches of both strains of PMP22-mutant mice, and these axonal deficits were more severe distally. Active axonal damage was only observed in the nerves of PMP22(0/0) mice. Despite the distinct effects on myelination and the Schwann cell phenotype that characterize the neuropathies of PMP22-mutant mice, both strains develop a distally accentuated axonopathy as a common disease mechanism which is likely to be responsible for the neurological deficits.

[Morphology and development of neural transplants of AMOG-deficient mice]. / Morphologie und Entwicklung Neuraler Transplantate von AMOG-defizienten Mäusen.

The adhesion molecule on glia (AMOG) has been reported to function as cell adhesion molecule and also to constitute the beta 2-subunit of the murine Na,K-ATPase. In order to elucidate these functions in vivo, Magyar et al. have generated mice carrying a targeted deletion of the AMOG gene. These mice exhibit behaviourally normal development till postnatal day P16. At this time, they develop muscular weakness, incoordination, and tremor. Death invariably occurs 24-36 hours after onset of the symptoms. Histological and ultrastructural examination of brain sections show enlarged ventricles, brain edema, and swelling of astrocyte end feet. However, no disturbances of the architecture or cell migration in the brain can be detected. In order to identify long-term consequences of AMOG deficiency which might not yet be detectable at the time of death, we have established a CNS grafting model. The embryonal brain anlage (E10.5-E13.5) was grafted into the caudoputamen of wild type mice. The graft recipients are sacrificed up to 7 months after the procedure. Both wild type and AMOG deficient grafts develop and form solid neural tissue with neurons, myelinated axons, glial cells, and ventricular structures, as shown by histological and immunocytochemical analysis. However, no differences in grafts derived from wild type, heterozygous, and AMOG-deficient donors can be detected. Proliferation has been examined by BrdU immunocytochemistry. The blood-brain barrier as examined by repeated magnetic resonance imaging after injection of Gadolinium-DTPA has been shown to be largely reconstituted five weeks after grafting.

Identification and characterization of a cDNA and the structural gene encoding the mouse epithelial membrane protein-1.

The PMP22/EMP/MP20 gene family includes four closely related proteins, peripheral myelin protein-22 (PMP22), epithelial membrane protein-1 (EMP-1), epithelial membrane protein-2 (EMP-2), and epithelial membrane protein-3 (EMP-3), which share amino acid identities ranging from 33 to 43%. In addition, the lens-specific membrane protein MP20 represents a more distant relative. Functionally, this family of proteins is likely to play important roles in the control of cell proliferation, cell differentiation, and cell death. In particular, mutations affecting the PMP22 gene are responsible for various hereditary peripheral neuropathies in humans and mice. We report the isolation and characterization of a mouse EMP-1 cDNA and the corresponding emp-1 gene. Mouse EMP-1 displays 93% amino acid identity to rat EMP-1 and 39% identity to mouse PMP22. The cDNA-predicted EMP-1 protein contains four putative membrane-associated domains and can be N-linked glycosylated in vitro. EMP-1 is encoded by a single-copy gene with the positions of introns exactly conserved between emp-1 and PMP22, corroborating the hypothesis that both genes belong to the same family. Computer-predicted structural domains of EMP-1 are partially mirrored by the exon/intron structure of emp-1. Most interestingly, exon 4, which covers the potential second transmembrane domain, a small intracellular loop, and half of the third transmembrane domain, encodes the most highly conserved regions between the EMP-1 and PMP22 proteins and is also remarkably conserved in the MP20 gene, indicating some shared functional significance for this module in the PMP22/EMP/MP20 family.

Progressive segregation of unmyelinated axons in peripheral nerves, myelin alterations in the CNS, and cyst formation in the kidneys of myelin and lymphocyte protein-overexpressing mice.

Myelin and lymphocyte protein (MAL) is a putative tetraspan proteolipid that is highly expressed by Schwann cells and oligodendrocytes as a component of compact myelin. Outside of the nervous system, MAL is found in apical membranes of epithelial cells, mainly in the kidney and stomach. Because MAL is associated with glycosphingolipids, it is thought to be involved in the organization, transport, and maintenance of glycosphingolipid-enriched membrane microdomains. In this report, we describe the generation and analysis of transgenic mice with increased MAL gene dosage. Immunohistochemical analysis revealed that the localization of MAL overexpression in the transgenic animals corresponded closely to the MAL expression pattern observed in wildtype animals, indicating correct spatial regulation of the transgene. Phenotypically, MAL overexpression led to progressive dissociation of unmyelinated axons from bundles in the PNS, a tendency to hypomyelination and aberrant myelin formation in the CNS, and the formation of large cysts in the tubular region of the kidney. Thus, increased expression of MAL appears to be deleterious to membranous structures in the affected tissues, indicating a requirement for tight control of endogenous MAL expression in Schwann cells, oligodendrocytes, and kidney epithelial cells.

Impaired differentiation of Schwann cells in transgenic mice with increased PMP22 gene dosage.

An intrachromosomal duplication containing the PMP22 gene is associated with the human hereditary peripheral neuropathy Charcot-Marie-Tooth disease type 1A, and PMP22 overexpression as a consequence of increased PMP22 gene dosage has been suggested as causative event in this frequent disorder of peripheral nerves. We have generated transgenic mice that carry additional copies of the pmp22 gene to prove that increased PMP22 gene dosage is sufficient to cause PNS myelin deficiencies. Mice carrying approximately 16 and 30 copies of the pmp22 gene display a severe congenital hypomyelinating neuropathy as characterized by an almost complete lack of myelin and marked slowing of nerve conductions. Affected nerves contain an increased number of nonmyelinating Schwann cells, which do not form onion bulbs but align in association with axons. The mutant Schwann cells are characterized by a premyelination-like state as indicated by the expression of embryonic Schwann cell markers. Furthermore, continued Schwann cell proliferation is observed into adulthood. We hypothesize that Schwann cells are impaired in their differentiation into the myelinating phenotype, leading to a disorder comparable to severe cases of hereditary motor and sensory neuropathies. Our findings, combined with the analysis of heterozygous and homozygous PMP22-deficient mice, indicate that aberrant pmp22 gene copy numbers cause various forms of myelination defects.

Recombinant Sindbis virus allows expression and precise targeting of proteins of the contractile apparatus in cultured cardiomyocytes.

Expression of epitope-tagged sarcomeric proteins in cardiomyocytes is a powerful approach for the characterization of interacting domains. Here, we report a new strategy for the study of the targeting of contractile proteins in cardiomyocytes by Sindbis virus (SIN)-mediated gene transfer. Two recombinant SIN were generated, one encoding the myosin-light chain MLC3f-eGFP fusion protein (SINrep5/MLC3f-eGFP), and the other encoding the alpha-actinin-DsRed fusion protein (SINrep5/alpha-actinin-DsRed). After infection of long-term cultured neonatal and adult rat cardiomyocytes with SINrep5/MLC3f-eGFP, the exogenous MLC3f-eGFP fusion protein localized to the sarcomeres. Freshly isolated rod-shaped ventricular cardiomyocytes infected with SINrep5/alpha-actinin-DsRed exhibited a correct incorporation of the newly synthesized alpha-actinin-DsRed fusion protein at the Z-band of the sarcomere. This allows the assumption that the exogenous protein is assembled into myofibrils in living cardiomyocy-tes using the same molecular interactions equally to the endogenous counterpart. It has been thus demonstrated that the SIN expression system makes possible the straightforward analysis of the localization of sarcomeric proteins in cultured cardiomyocytes and may offer new possibilities for the characterization of mutant proteins involved in hypertrophic cardiomyopathies.

The AMOG/beta 2 subunit of Na,K-ATPase is not necessary for long-term survival of telencephalic grafts.

Adhesion molecule on glia (AMOG) represents the beta 2-subunit of murine Na,K-ATPase. Mice carrying a targeted deletion of the AMOG/beta 2 gene exhibit tremor and limb paralysis at postnatal day (P) 15 and die 2 days after the onset of symptoms. The brains of these mice show edema and swelling of astrocytic end feet. However, the cause of death has remained unclear. To identify long-term consequences of AMOG/beta 2 deficiency, we have grafted parts of the embryonic telencephalic anlage of AMOG/beta 2-deficient mice into the caudoputamen of wild-type mice and analyzed the grafts up to 500 days after transplantation. Histological, immunocytochemical, and in situ hybridization techniques were applied to examine histoarchitecture, proliferation, differentiation, and long-term survival of grafts. AMOG/beta 2-deficient telencephalic grafts develop normally and form solid neural tissue that cannot be distinguished from control grafts by morphological features or with immunocytochemical stains for neuronal and glial markers. No signs of degeneration can be found. Expression analysis, however, revealed that no AMOG/beta 2 protein of possible host origin can be detected in AMOG/beta 2-deficient grafts. Graft-borne astrocytes express neither the AMOG/beta 1 nor the AMOG/beta 2 subunit of Na,K-ATPase as examined with immunocytochemistry and in situ hybridization. These findings indicate that AMOG/beta 2 is not necessary for long-term survival of telencephalic graft tissue.