Epithelial membrane protein-1, peripheral myelin protein 22, and lens membrane protein 20 define a novel gene family

Chromosomal mapping of Tmp (Emp1), Xmp (Emp2), and Ymp (Emp3), genes encoding membrane proteins related to Pmp22

We have recently characterized a novel mammalian gene family, encoding membrane glycoproteins with four trans-membrane domains. This gene family includes the previously studied PMP22, which is involved in the Charcot-Marie-Tooth neuropathy, and three novel genes: TMP, XMP, and YMP (HGMW-approved symbols EMP1, EMP2 and EMP3, respectively). The Tmp (tumor-associated membrane protein) gene was isolated from a c-myc induced mouse brain tumor and is expressed in several highly proliferative cell types. We have now isolated cDNAs of the mouse Xmp and Ymp genes and determined the chromosomal localization of mouse Tmp, Xmp, and Ymp. Tmp was mapped to mouse chromosome 6, Xmp was mapped to chromosome 16, and Ymp was mapped to chromosome 7. Tmp and Ymp map to paralogous chromosomal regions, whereas Xmp maps to a chromosomal region that is putatively paralogous to a region on chromosome 11, to which Pmp22 was previously mapped. These data suggest that this family of membrane glycoproteins evolved as a result of chromosomal duplications.

Structural arrangement of lens fiber cell plasma membrane protein MP20

The membrane topology of the bovine lens fiber cell plasma membrane protein MP20 has been examined using anti-peptide antibodies and the hydrophobic label 3-(trifluoromethyl)-3-(m-[125I]iodophenyl)diazerine ([125I]TID). The specificity of the affinity-purified anti-peptide polyclonal antibodies, directed against four separate hydrophilic segments of MP20, was established by immunodot blots, Western immunoblotting and ELISA. Western immunodetection of protease-treated, urea-washed lens membranes indicated that each of the segments of MP20 identified by the anti-peptide antibodies was accessible to proteases indicating their likely extramembranous location. Immunoelectron microscopy of junctional lens membrane immunolabeled with MP20 anti-peptide antibodies directed against two segments predicted to be on the extra-cellular face of the lens fiber cell plasma membrane suggests these segments may actually be located on the cytoplasmic plasma membrane face. Transmembrane segments of MP20, identified using the hydrophotic photo-affinity label [125I]TID, were isolated and sequenced. Only three of the four previously proposed transmembrane segments of this protein were significantly labeled with this reagent. Based on these results and previously reported information regarding MP20, a new topological model is proposed for the arrangement of MP20 in the lens fiber cell plasma membrane. The new topological model of MP20 includes two alpha-helical and two beta-strand transmembrane segments.

Molecular analysis of two mammary carcinoma cell lines at the transcriptional level as a model system for progression of breast cancer

As a model system for the identification of genes involved in the progression of human breast cancer, differential gene expression in cell lines MCF-7 and MCF-7ADR was investigated. The latter cell line is derived from the former. Cell line MCF-7 is estrogen receptor-positive, vimentin-negative and uninvasive in the Matrigel outgrowth assay and in the nude mouse, while MCF-7ADR is estrogen receptor-negative, hormone-resistant, vimentin-positive, invasive in the Matrigel outgrowth assay and in the nude mouse and resistant to adriamycin due to overexpression of glycoprotein gp170. We have shown that tumor progression in this model system is mediated by transcriptional regulation of mitochondria-related genes, proteases, transmembrane receptors and cell cycle-related gene proteins. Among the genes differentially regulated at the transcriptional level in the cell lines MCF-7 and MCF-7ADR are a new mitochondrial transcript, mitochondrial creatine kinase, matrix metalloproteinase-1, stromelysin-3, urokinase and its receptor, tissue factor, E-cadherin, epidermal growth factor receptor, transmembrane proteins Mat-8 and progression associated protein (PAP), cyclin E, cyclin-dependent kinase-2 and cell cycle inhibitory proteins p16, p21 and p27.

Analysis of compound heterozygous mice reveals that the Trembler mutation can behave as a gain-of-function allele

The most common form of Charcot-Marie-Tooth disease, CMT1A, is correlated with a 1.5 megabase duplication on chromosome 17p.11.2 containing the peripheral myelin protein 22 (PMP22) gene. Deletion of the same region is associated with a second inherited neural disorder, the hereditary neuropathy with liability to pressure palsies (HNPP). Moreover, several distinct point mutations within the PMP22 coding region are associated with CMT1A and Dejerine-Sottas Syndrome in humans and the Trembler (Tr) and Trembler-J phenotypes in mice. Heterozygous Tr mutants (Tr/+) display severe hypomyelination of peripheral nerve fibers while heterozygous pmp22 knockout mice (pmp22+/0) are characterized by focal hypermyelination. These findings suggest that the Tr mutation does not generate a pmp22 null allele but rather produces its deleterious effects by either a dominant-negative or gain-of-function mechanism. To address this question in detail, we have compared various combinations of pmp22 alleles including Tr/+, Tr/Tr, Tr/0, pmp22+/0, and pmp22(0/0) mice with respect to the resulting myelin abnormalities. The combined analysis of these mutants demonstrates that the Tr allele can act as a true gain-of-function mutation in both, the heterozygous state on a null background (Tr/0) as well as in homozygous Tr animals (Tr/Tr). Furthermore, increasing the relative Tr gene dosage correlates with more pronounced myelin deficiencies and decreased levels of MBP and P0 in 18-day-old mice.

HNMP-1: a novel hematopoietic and neural membrane protein differentially regulated in neural development and injury

The hnmp-1 (hematopoietic neural membrane protein) gene encodes a protein with striking similarity to the tetra-transmembrane-spanning protein encoded by pmp22. hnmp-1 was cloned from an elutriated human monocyte library and is expressed in various human hematopoietic and lymphoid lineages as well as adult mouse spleen and thymus. In the mouse nervous system, HNMP-1 mRNA is temporally expressed by Schwann cells during sciatic nerve myelination. Dorsal root ganglia sensory and spinal cord alpha-motoneurons acquire HNMP-1 protein selectively throughout development. In the fiber tracts of the spinal cord and in sciatic nerve, HNMP-1 protein is axon-associated. Additionally a rapid and sustained level of HNMP-1 expression is observed in response to acute PNS injury. HNMP-1 is constituitively induced in sciatic nerve of Trembler J mice, which are mutant for pmp22 and have a demyelinating/hypomyelinating phenotype. The expression pattern of HNMP-1 suggests a possible role for this molecule during active myelination.

Heterozygous peripheral myelin protein 22-deficient mice are affected by a progressive demyelinating tomaculous neuropathy

Hereditary neuropathy with liability to pressure palsy (HNPP) is associated with a heterozygous 1.5 megabase deletion on chromosome 17 that includes the peripheral myelin protein (PMP) gene PMP22. We show that heterozygous PMP22 knock-out mice, which carry only one functional pmp22 allele and thus genetically mimic HNPP closely, display similar morphological and electrophysiological features as observed in HNPP nerves. As reported previously, focal hypermyelinating structures called tomacula, the pathological hallmarks of HNPP, develop progressively in young PMP22(+/0) mice. By following the fate of tomacula during aging, we demonstrate now that these mutant animals are also interesting models for examining HNPP disease mechanisms. Subtle electrophysiological abnormalities are detected in PMP22(+/0) mice >1 year old, and a significant number of abnormally swollen and degenerating tomacula are present. Thinly myelinated axons and supernumerary Schwann cells forming onion bulbs as fingerprints of repeated cycles of demyelination and remyelination are also encountered frequently. Quantitative analyses using electron microscopy on cross sections and light microscopy on single teased nerve fibers suggest that tomacula are intrinsically unstable structures that are prone to degeneration; however, the severity of morphological and electrophysiological abnormalities in PMP22(+/0) mice is variable. These combined findings are reminiscent of the disease progression in HNPP and offer a possible explanation about why some HNPP patients develop a chronic motor and sensory neuropathy later in life that resembles demyelinating forms of Charcot-Marie-Tooth disease by both morphological and clinical criteria.

Abnormal Schwann cell/axon interactions in the Trembler-J mouse

The Trembler-J (TrJ) mouse has a point mutation in the gene coding for peripheral myelin protein 22 (PMP22). Disturbances in PMP22 are associated with abnormal myelination in a range of inherited peripheral neuropathies both in mice and humans. PMP22 is produced mainly by Schwann cells in the peripheral nervous system where it is localised to compact myelin. The function of PMP22 is unclear but its low abundance (approximately 5% of total myelin protein) means that it is unlikely to play a structural role. Its inclusion in a recently discovered family of proteins suggests a function in cell proliferation/differentiation and possibly in adhesion. Nerves from TrJ and the allelic Trembler (Tr) mouse are characterised by abnormally thin myelin for the size of the axon and an increased number of Schwann cells. We report ultrastructural evidence of abnormal Schwann cell-axon interactions. Schwann cell nuclei have been found adjacent to the nodes of Ranvier whereas in normal animals they are located near the centre of the internodes. In some fibres the terminal myelin loops faced outwards into the extracellular space instead of turning inwards and terminating on the axon. In severely affected nerves many axons were only partially surrounded by Schwann cell cytoplasm. All these features suggest a failure of Schwann cell-axon recognition or interaction. In addition to abnormalities related to abnormal myelination there was significant axonal loss in the dorsal roots.

cDNA cloning, genomic structure, and chromosome mapping of the human epithelial membrane protein CL-20 gene (EMP1), a member of the PMP22 family

CL-20 is a novel gene encoding a protein that is structurally related to but distinct from the peripheral myelin protein PMP22. Like PMP22, CL-20 is likely to play important roles in the regulation of cell proliferation, differentiation, and cell death. In this study, we describe the cloning and sequencing of a cDNA encoding the human homologue of CL-20 and characterize the genomic structure of this gene. The hCL-20 gene (HGMW-approved symbol EMP1) encodes a protein of 157 amino acids that exhibits 76% identity to the rabbit CL-20 and to the rat EMP-1, which have been described recently, and 39% identity to human PMP22. CL-20 contains four hydrophobic domains, suggesting that it is an integral membrane protein. In particular the second hydrophobic domain encoded within the fourth exon is highly conserved among CL-20, EMP-1, and PMP22, suggesting a functional role for this region. CL-20 mRNA is abundant in squamous-differentiated bronchial epithelial cells; however, low levels of CL-20 mRNA can be detected in several human tissues by Northern analysis. Retinoic acid, which inhibits squamous differentiation, represses CL-20 expression in normal human bronchial epithelial cells. The genomic structure of the hCL-20 gene was analyzed using a P1 vector containing this gene. The hCL-20 gene contains five exons about 0.2, 0.12, 0.1, 0.14, and 2.2 kb and four introns about 15, 1.9, 0.1, and 0.7 kb. We have mapped the hCL-20 gene to chromosome 12p12 by fluorescence in situ hybridization.

Aberrant protein trafficking in Trembler suggests a disease mechanism for hereditary human peripheral neuropathies

The naturally occurring mouse mutant Trembler (Tr) represents an animal model for inherited human neuropathies caused by point mutations affecting peripheral myelin protein 22 (PMP22). We describe the likely pathogenic cellular mechanism underlying the observed myelin deficiency. In Tr/+ animals, PMP22 immunoreactivity was found not only in compact myelin but also abundantly in the cytoplasm of Schwann cells. Based on these observations, the biosynthesis of wildtype and Tr protein was examined in transfected cells. While wildtype PMP22 was readily transported to the plasma membrane, Tr protein was localized mainly in the endoplasmic reticulum. Coexpression revealed a dominant effect of Tr on protein trafficking of wildtype PMP22. In agreement with the findings in vitro, Tr protein was not detectable in myelin of Tr/0 mice.

Characterization of a tumor-associated gene, a member of a novel family of genes encoding membrane glycoproteins

To isolate genes involved in tumor formation and in embryogenesis, a subtracted cDNA library was constructed from a c-myc-induced mouse brain tumor. A gene isolated in this screen, named TMP (tumor-associated membrane protein), codes for a putative glycoprotein with four transmembrane domains. The TMP gene was found to be highly expressed in brain tumor cells but not in normal brain. It is also expressed at high levels in undifferentiated embryonic stem cells, but markedly down-regulated in these cells after their differentiation into embryoid bodies. The TMP amino acid sequence bears high homology to the growth arrest specific protein PMP22/GAS-3, which is involved in several human peripheral neuropathies. The expression patterns of the TMP and PMP22 genes in NIH-3T3 fibroblasts were compared at different proliferation states. The results suggest an inverse pattern of expression for the two homologs, TMP expression being high during cell proliferation and PMP22 expression being high during growth arrest. To further characterize the TMP gene we have isolated its human homolog and examined its expression in embryonic and adult tissues. In our search for human sequences homologous to TMP and PMP22, we identified two new genes which we have named XMP and YMP. Thus, we present a novel family of membrane glycoproteins, one member of which is closely associated with proliferation and another with growth arrest.

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.

Epithelial membrane protein-2 and epithelial membrane protein-3: two novel members of the peripheral myelin protein 22 gene family

Peripheral myelin protein 22 (PMP22) is expressed by Schwann cells in the peripheral nervous system (PNS), and mutations affecting the PMP22 gene are associated with hereditary motor and sensory neuropathies. We have previously defined the PMP22/EMP/MP20 gene family by characterizing the PMP22-related epithelial membrane protein-1 (EMP-1). We now report the identification of two additional members of the same family, epithelial membrane protein-2 and epithelial membrane protein-3 (EMP-2 and EMP-3). Both cDNA-predicted polypeptides share approx. 40% aa identity with PMP22. In human, EMP-2 and EMP-3 mRNA transcripts are found in most tissues with an expression pattern partially overlapping that of PMP22 and EMP-1. EMP-2 is most prominently expressed in the adult ovary, heart, lung and intestine and in fetal lung. The levels of EMP-3 transcripts are highest in peripheral blood leukocytes, ovary, intestine and various embryonic tissues. In contrast to PMP22 and EMP-1, EMP-2 and EMP-3 expression is detectable in the liver. In vitro transcription-translation generates EMP-2 and EMP-3 polypeptides of 18 kDa which is in agreement with their predicted sizes. Since PMP22 has been implicated in the regulation of cell proliferation and apoptosis, it appears likely that these novel members of the PMP22/EMP/MP20 protein family are also involved in similar regulatory processes in a variety of tissues.