Expression of Drosophila MAGE gene encoding a necdin homologous protein in postembryonic neurogenesis

The MAGE (melanoma antigen) family is characterized by a large conserved domain termed MAGE homology domain. Originally identified MAGE genes encoding tumor rejection antigens are expressed only in cancers and male germ cells. Necdin, which contains the MAGE homology domain, is highly expressed in postmitotic cells such as neurons and skeletal muscle cells. The human necdin gene NDN is transcribed only from the paternal allele through genomic imprinting, and its deficiency is implicated in the pathogenesis of the neurodevelopmental disorder Prader-Willi syndrome. Although over 30 MAGE genes have been identified in humans, fruit fly (Drosophila melanogaster) has only a single MAGE gene that encodes a protein similar to necdin homologous MAGE proteins. In this study, we analyzed the spatiotemporal expression patterns of MAGE mRNA and the encoded protein during fly development. Whole-mount embryo in situ hybridization analysis revealed that MAGE mRNA was highly expressed at the syncytial blastoderm stage and in the ventral and procephalic neurogenic regions of the ectoderm during gastrulation. In contrast, MAGE expression was nearly undetectable in postmitotic neurons of the central nervous system at late embryonic stages. During postembryonic neurogenesis, MAGE was highly expressed in neural stem cells (neuroblasts) and their progeny (ganglion mother cells and postmitotic neurons) at larval and pupal stages. MAGE was also expressed in postmitotic neurons including mushroom body neurons and retinal photoreceptors in adulthood. These results indicate that MAGE expression lasts throughout the postembryonic neurogenesis in Drosophila.     

Functional domains of necdin for protein-protein interaction, nuclear matrix targeting, and cell growth suppression

Necdin is a growth suppressor expressed predominantly in postmitotic neurons. The necdin gene is involved in the etiology of the genomic imprinting-associated neurodevelopmental disorder Prader-Willi syndrome and belongs to the MAGE gene family. All the MAGE family proteins contain a large homology domain termed the MAGE homology domain (MHD). We here characterize the regions of necdin required for the protein-protein interaction, nuclear matrix targeting, and cell growth suppression. The region including entire MHD (amino acids 116-280) of necdin was required for its interaction with p53, while the regions amino acids 144-184 and 191-222 within the MHD were required for both the nuclear matrix targeting and the cell growth suppression of osteosarcoma SAOS-2 cells. The amino-terminal proline-rich acidic region (amino acids 60-100) was also necessary for cell growth suppression. Tetracycline-regulatable overexpression of necdin induced growth arrest of SAOS-2 cells in a reversible manner, and the necdin-overexpressing cells showed a large, flattened morphology with double nuclei. In contrast, a necdin mutant lacking amino acids 191-222 did not induce such changes. These findings suggest that different functions of necdin are mediated via its distinct domains.     

The p75 neurotrophin receptor interacts with multiple MAGE proteins

The p75 neurotrophin receptor has been implicated in diverse aspects of neurotrophin signaling, but the mechanisms by which its effects are mediated are not well understood. Here we identify two MAGE proteins, necdin and MAGE-H1, as interactors for the intracellular domain of p75 and show that the interaction is enhanced by ligand stimulation. PC12 cells transfected with necdin or MAGE-H1 exhibit accelerated differentiation in response to nerve growth factor. Expression of these two MAGE proteins is predominantly cytoplasmic in PC12 cells, and necdin was found to be capable of homodimerization, suggesting that it may act as a cytoplasmic adaptor to recruit a signaling complex to p75. These findings indicate that diverse MAGE family members can interact with the p75 receptor and highlight type II MAGE proteins as a potential family of interactors for signaling proteins containing type II death domains.     

Xp21 contiguous gene syndromes: deletion quantitation with bivariate flow karyotyping allows mapping of patient breakpoints.

Bivariate flow karyotyping was used to estimate the deletion sizes for a series of patients with Xp21 contiguous gene syndromes. The deletion estimates were used to develop an approximate scale for the genomic map in Xp21. The bivariate flow karyotype results were compared with clinical and molecular genetic information on the extent of the patients' deletions, and these various types of data were consistent. The resulting map spans > 15 Mb, from the telomeric interval between DXS41 (99-6) and DXS68 (L1-4) to a position centromeric to the ornithine transcarbamylase locus. The deletion sizing was considered to be accurate to +/- 1 Mb. The map provides information on the relative localization of genes and markers within this region. For example, the map suggests that the adrenal hypoplasia congenita and glycerol kinase genes are physically close to each other, are within 1-2 Mb of the telomeric end of the Duchenne muscular dystrophy (DMD) gene, and are nearer to the DMD locus than to the more distal marker DXS28 (C7). Information of this type is useful in developing genomic strategies for positional cloning in Xp21. These investigations demonstrate that the DNA from patients with Xp21 contiguous gene syndromes can be valuable reagents, not only for ordering loci and markers but also for providing an approximate scale to the map of the Xp21 region surrounding DMD.     

Structural characterization and chromosomal localization of the MAGE-E1 gene

Genes of the melanoma-associated antigen (MAGE) family are characterized by the expression of tumor antigens on a malignant melanoma recognized by autologous cytolytic T lymphocytes. We have previously identified novel members of the MAGE gene family expressed in human glioma and named them MAGE-E1a-c. In the present study, we have revealed the genomic structure of MAGE-E1 by sequence analysis of a human chromosome bacterial artificial chromosome clone containing the MAGE-E1 gene. The MAGE-E1 gene is composed of 13 exons, and three of these (exon 2, exon 3 and exon 12) are alternatively spliced in each variant (E1a-c). The open reading frame encoding the MAGE-E1 peptides initiates in exon 2 and ends in exon 13. We have also demonstrated that the MAGE-E1 gene is located in Xp11 through the analysis of radiation hybrid panels. The genomic structure of MAGE-E1 is markedly similar to that of MAGE-D and its chromosomal locus is also identical to that of MAGE-D, but these features contrast with those of other MAGEs. These results suggest that MAGE-D and -E1 may be evolutionarily distant from other members of the MAGE family, and the two may be ancestral genes for the others.     

A new gene family (FAM9) of low-copy repeats in Xp22.3 expressed exclusively in testis: implications for recombinations in this region

Illegitimate recombinations between low-copy repetitive elements (LCR) have been implicated in the pathogenesis of various chromosomal rearrangements. Two such duplicons have been reported previously on Xp22.3, the CRI-S232 elements, involved in the generation of deletions in the steroidsulfatase gene and five members of the G1.3 (DXF22S) repetitive sequence family. By molecular characterization of an Xp22/10q24 translocation, we identified one duplicon of the G1.3 family in the breakpoint region in Xp22.3. We show that G1.3 elements harbor at least three expressed genes, FAM9A, FAM9B, and FAM9C, and three putative pseudogenes, all mapped to Xp22.33-p22.31. The deduced amino acid sequence of the three novel proteins shows homology to SYCP3, a component of the synaptonemal complex located along the paired chromosomes during meiosis. FAM9A, FAM9B, and FAM9C are expressed exclusively in testis; their proteins are located in the nucleus, and FAM9A localizes to the nucleolus. The presence of genes within duplicons may represent putative recombination-promoting factors for actively transcribed genes in meiotic cells, with the resulting open chromatin structure facilitating unequal crossing-over events and chromosomal rearrangements.     

Sequence and expression pattern of the human MAGE2 gene

We reported previously identification of the human MAGE1 gene, which encodes an antigen recognized on human melanoma MZ2-MEL by autologous cytolytic T lymphocytes. In addition to MAGE1, melanoma MZ2-MEL expresses several closely related genes, one of which has been named MAGE2. The complete MAGE2 sequence was obtained and it comprises 3 exons homologous to those of MAGE1 and an additional exon homologous to a region of the first MAGE1 intron. Like the open reading frame of MAGE1, that of MAGE2 is entirely encoded by the last exon. The MAGE1 and MAGE2 sequences of this exon show 82% identity and the putative proteins show 67% identity. The MAGE2 gene is expressed in a higher proportion of melanoma tumors than MAGE1. It is also expressed in many small-cell lung carcinomas and other lung tumors, laryngeal tumors, and sarcomas. No MAGE1 and MAGE2 gene expression was found in a large panel of healthy adult tissues, with the exception of testis.The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide sequence database and have been assigned the accession number L18920.     

MAGE-F1, a novel ubiquitously expressed member of the MAGE superfamily

Most known members of the MAGE superfamily are expressed in tumors, testis and fetal tissues, which has been described as a cancer/testis or "CT" expression pattern. We have identified a novel member of this superfamily, MAGE-F1, which is expressed in all adult and fetal tissues tested. In addition to normal tissues, MAGE-F1 is expressed in many tumor types including ovarian, breast, cervical, melanoma and leukemia. MAGE-F1 is encoded on chromosome 3, identifying a sixth chromosomal location for a MAGE superfamily gene. The coding region of MAGE-F1 is contained within a single exon and includes a microsatellite repeat. Sequence analysis and expression profiles define a new class of ubiquitously expressed MAGE superfamily genes that includes MAGE-F1, MAGE-D1, MAGE-D2/JCL-1 and NDN. The finding that several MAGE genes are ubiquitously expressed suggests a role for MAGE encoded proteins in normal cell physiology. Furthermore, potential cross-reactivity to these ubiquitously expressed MAGE gene products should be considered in the design of MAGE-targeted immunotherapies for cancer.     

Xp-duplications with and without sex reversal

Duplications in Xp including the DSS (dosage sensitive sex reversal) region cause male to female sex reversal. We investigated two patients from families with Xp duplications. The first case was one of two sisters with karyotype 46,XY, der(22), t(X;22)(p11.3;p11)mat and unambiguous female genitalia. The living sister was developmentally retarded, and showed multiple dysmorphic features and an acrocallosal syndrome. The second case was a boy with a maternally inherited direct duplication of Xp21.3-pter with the breakpoint close to the DSS locus. He had multiple abnormalities and micropenis, but otherwise unambiguous male genitalia. We performed quantitative Southern blot analysis with probes from Xp22.13 to p21.2 to define the duplicated region. Clinical, cytogenetic, and molecular data from both patients were compared with those of previously reported related cases. A comparison of the extragenital symptoms revealed no differences between patients with or without sex reversal. In both cases, the symptoms were non-specific. Among 22 patients with a duplication in Xp, nine had unambiguous female genitalia and a well-documented duplication of the DSS region. Two patients with duplication of DSS showed ambiguous external genitalia. From these data, we conclude that induction of testicular tissue may start in these patients, but that the type of genitalia depends on the degree of subsequent degeneration by a gene in DSS.     

Necdin Enhances Myoblasts Survival by Facilitating the Degradation of the Mediator of Apoptosis CCAR1/CARP1

Regeneration of muscle fibers, lost during pathological muscle degeneration or after injuries, is sustained by the production of new myofibers by means of the satellite cells. Survival of the satellite cells is a critical requirement for efficient muscle reconstitution. Necdin, a member of the MAGE proteins family, is expressed in satellite cell-derived myogenic precursors during perinatal growth and in the adult upon activation during muscle regeneration, where it plays an important role both in myoblast differentiation and survival. We show here that necdin exerts its pro-survival activity by counteracting the action of the pro-apoptotic protein Cell Cycle Apoptosis Regulatory Protein (CCAR1/CARP1) that we have identified as a new molecular interactor of necdin by two-hybrid screening. Necdin is responsible for the maintenance of CCAR1 protein levels, by implementing its ubiquitination and degradation through the proteasome. Taken together, these data shed new light on the molecular mechanism of necdin anti-apoptotic activity in myogenesis.     

人Xp21．1－p21．3上3．5MbYAC重叠群构建及物理图谱分析

用Ａｌｕ－ＰＣＲ指纹图谱法分析了人Ｘｐ２１．１－ｐ２１．３上一系列的酵母人工染色体（ｙｅａｓｔａｒｔｉｆｉｃｉａｌｃｈｒｏｍｏｓｏｍｅ,ＹＡＣ）克隆,发现其中的两个ＹＡＣ克隆构成包含ＤＸＳ１６６位点的重叠群,而且这一重叠群与以前构建的包含ＤＭＤ基因全序列的ＹＡＣ重叠群相连接,ＹＡＣ克隆末端探针交叉杂交证实了这一重叠,使这一ＹＡＣ重叠群至少延伸至ＤＸＳ１６６位点,形成一个跨度为３．５Ｍｂ的ＹＡＣ重叠群。基于这些重叠的ＹＡＣ克隆绘制了这一区域的大尺度限制酶切图谱,并在这一图谱上定位了ＤＸＳ１６６位点,从而确定了ＤＸＳ１６６位点与ＤＭＤ基因的物理关系。这一工作为ＤＭＤ基因的５＇远端调控作用研究及该区域未知基因的克隆奠定了基础。     

Genome of Xanthomonas oryzae bacteriophage Xp10: an odd T-odd phage

Xp10 is a lytic bacteriophage of the phytopathogenic bacterium Xanthomonas oryzae. Though morphologically Xp10 belongs to the Syphoviridae family, it encodes its own single-subunit RNA polymerase characteristic of T7-like phages of the Podoviridae family. Here, we report the determination and analysis of the 44,373 bp sequence of the Xp10 genome. The genome is a linear, double-stranded DNA molecule with 3' cohesive overhangs and no terminal repeats or redundancies. Half of the Xp10 genome contains genes coding for structural proteins and host lysis functions in an arrangement typical for temperate dairy phages that are related to the Escherichia coli lambda phage. The other half of the Xp10 genome contains genes coding for factors of host gene expression shut-off, enzymes of viral genome replication and expression. The two groups of genes are transcribed divergently and separated by a regulatory region, which contains divergent promoters recognized by the host RNA polymerase. Xp10 has apparently arisen through a recombination between genomes of widely different phages. Further evidence of extensive gene flux in the evolution of Xp10 includes a high fraction (10%) of genes derived from an HNH-family endonuclease, and a DNA-dependent DNA polymerase that is closer to a homolog from Leishmania than to DNA polymerases from other phages or bacteria.     

Identification of a new, unorthodox member of the MAGE gene family.

Several tumor-associated antigen families, such as MAGE, GAGE/PAGE, PRAME, BAGE, and LAGE/NY-ESO-1, exist. These antigens are of particular interest in tumor immunology, because their expression, with exception of testis and fetal tissues, seems to be restricted to tumor cells only. We have identified a novel member of the MAGE gene family, MAGED1. Northern hybridization and RT-PCR demonstrated that the expression level of MAGED1 in different normal adult tissues is comparable to that in testis and fetal liver. Thus, MAGED1 does not possess an expression pattern characteristic of previously identified MAGE family genes, suggesting that the biology of the MAGE-family genes is more complex than previously thought. Chromosome mapping linked MAGED1 to marker AFM119xd6 (DXS1039) on chromosome Xp11.23.     

Mapping of a new SGBS locus to chromosome Xp22 in a family with a severe form of Simpson-Golabi-Behmel syndrome.

Simpson-Golabi-Behmel syndrome (SGBS) is an X-linked overgrowth syndrome with associated visceral and skeletal abnormalities. Alterations in the glypican-3 gene (GPC3), which is located on Xq26, have been implicated in the etiology of relatively milder cases of this disorder. Not all individuals with SGBS have demonstrated disruptions of the GPC3 locus, which raises the possibility that other loci on the X chromosome could be responsible for some cases of this syndrome. We have previously described a large family with a severe form of SGBS that is characterized by multiple anomalies, hydrops fetalis, and death within the first 8 wk of life. Using 25 simple tandem-repeat polymorphism markers spanning the X chromosome, we have localized the gene for this disorder to an approximately 6-Mb region of Xp22, with a maximum LOD score of 3.31 and with LOD scores <-2.0 for all of Xq. These results demonstrate that neither the GPC3 gene nor other genes on Xq26 are responsible for all cases of SGBS and that a second SGBS locus resides on Xp22.     

Congenital adrenal hypoplasia, myopathy, and glycerol kinase deficiency: Molecular genetic evidence for deletions

Glycerol kinase deficiency (GKD) is an X-linked recessive trait that occurs in association with congenital adrenal hypoplasia (AH) and developmental delay with or without congenital dystrophic myopathy. Several such patients have recently been reported to have cytological deletions of chromosome region Xp21 and/or of DNA markers that map near the locus for Duchenne muscular dystrophy (DMD) in band Xp21. We have examined the initial family reported in the literature and, using prometaphase chromosome studies and Southern blot analysis with 13 different DNA probes derived from band Xp21, have found no deletions within this region of the X chromosome. When DNA samples from six other unrelated affected males were analyzed, four of them were found to have different-size deletions within Xp21. Thus, the form of GKD associated with AH and dystrophic myopathy exhibits significant genetic heterogeneity at the DNA level. No deletions were detected in two patients with isolated GK deficiency. Comparison of our molecular studies of unrelated patients with deletions of DNA segments allows us to define the region of Xp21 (between probes J-Bir and L1.4) that most likely contains the genes for GKD and AH. This location is distal to the DMD locus. The patients with progressive muscular dystrophy tended to have larger deletions that include markers known to derive from the DMD locus, while GKD/AH/dystrophic-myopathy patients without current evidence of deletion seemed to have a milder, nonprogressive form of congenital myopathy.