A New Family of Mouse Genes Homologous to the HumanMAGEGenes

The humanMAGEgenes are expressed in a wide variety of tumors but not in normal cells, with the exception of the male germ cells, placenta, and, possibly, cells of the developing embryo. These genes encode tumor-specific antigens recognized by cytolytic T lymphocytes. TheMAGEgenes are located on the X chromosome, in three clusters denotedMAGE-A, B,andC,mapping at q28, p21.3, and q26, respectively. The function of these genes remains unknown. Because mice offer many advantages for the study of genes that may be involved in embryonic development, we looked for the murine equivalents of the 12 humanMAGE-Agenes. Using aMAGE-Aprobe, we isolated 8 new murine genes that are homologous to theMAGEgenes. On average, the open reading frames (ORFs) of these 8 closely related genes display a slightly higher degree of nucleotide identity with theMAGE-AORFs than with theMAGE-BorMAGE-CORFs. Furthermore, likeMAGE-Agenes, they encode acidic proteins, whereas theMAGE-Bgenes encode basic proteins. Accordingly, these 8 murine genes were namedMage-a1to8(approved symbolsMagea1to8).Mage-agenes were mapped in two different loci on the mouse X chromosome.Mage-a4andMage-a7are located in a region that is syntenic to either Xp21 or Xq28. The 6 other genes are arranged in a cluster located in a region syntenic to Xp22. Like their human counterparts,Mage-agenes were found to be transcribed in adult testis, but not in other tissues. Expression of someMage-agenes was also detected in tumor cell lines. TwoMage-agenes were found to be expressed in blastocysts.     

Four Ubiquitously Expressed Genes,RD(D6S45)–SKI2W(SKIV2L)–DOM3Z–RP1(D6S60E), Are Present between Complement Component Genes FactorBandC4in the Class III Region of the HLA

The association of the HLA class III region with many diseases motivates the investigation of unidentified genes in the 30-kb segment between complement component genesBfandC4. RD,which codes for a putative RNA binding protein, is 205 bp downstream ofBf. SKI2W(HGMW-approved symbol SKIV2L), a DEVH-box gene probably involved in RNA turnover, is 171 bp downstream ofRD(HGMW-approved symbol D6S45).RP1(HGMW-approved symbol D6S60E) is located 611 bp upstream ofC4.The DNA sequence between humanRDandRP1was determined and the exon–intron structure ofSKI2Welucidated.SKI2Wconsists of 28 exons. The putative RNA helicase domain of Ski2w is encoded by 9 exons. Further analysis of the 2.5-kb intergenic sequence betweenSKI2WandRP1led to the discovery ofDOM3Z.The full-length cDNA sequence ofDOM3Zencodes 396 amino acids with a leucine zipper motif. Dom3z-related proteins are present in simple and complex eukaryotes. InCaenorhabditis elegans,Dom3z-related protein could be involved in the development of germ cells. HumanRD–SKI2WandDOM3Z–RP1are arranged as two head-to-head oriented gene pairs with unmethylated CpG sequences at the common 5′ regulatory region of each gene pair. The ubiquitous expression pattern suggests that these four genes are probably housekeeping genes.     

Chemokine PARC Gene (SCYA18) Generated by Fusion of Two MIP-1α/LD78α-like Genes

Two loci in the human genome, chromosomes 4q12–q21 and 17q11.2, contain clusters of CXC and CC chemokine subfamily genes, respectively. Since mice appear to contain fewer chemokine genes than humans, numerous gene duplications might have occurred in each locus of the human genome. Here we describe the genomic organization of the human pulmonary and activation-regulated CC chemokine (PARC), also known as DC-CK1 and AMAC-1. Despite high sequence similarity to a CC chemokine macrophage inflammatory protein-1α (MIP-1α)/LD78α, PARC is chemotactic for lymphocytes and not for monocytes and does not share its receptor with MIP-1α. Analyses of the BAC clones containing the humanPARCgene indicated that the gene is located most closely toMIP-1α(HGMW-approved symbolSCYA3) andMIP-1β(HGMW-approved symbolSCYA4) on chromosome 17q11.2. Dot-plot comparison suggested that thePARCgene had been generated by fusion of twoMIP-1α-like genes with deletion and selective usage of exons. Base changes accumulated before and after the fusion might have adapted the gene to a new function. Since there are variably duplicated copies of theMIP-1αgene calledLD78β(HGMW-approved symbolSCYA3L) in the vicinity of theMIP-1αgene, the locus surrounding theMIP-1αgene seems to be a “hot spring” that continuously produces new family genes. This evidence provides a new model, duplication and fusion, of the molecular basis for diversity within a gene family.     

Chromosomal Localization of the Human and Mouse Hyaluronan Synthase Genes

We have recently identified a new vertebrate gene family encoding putative hyaluronan (HA) synthases. Three highly conserved related genes have been identified, designatedHAS1, HAS2,andHAS3in humans andHas1, Has2,andHas3in the mouse. All three genes encode predicted plasma membrane proteins with multiple transmembrane domains and approximately 25% amino acid sequence identity to theStreptococcus pyogenesHA synthase, HasA. Furthermore, expression of any oneHASgene in transfected mammalian cells leads to high levels of HA biosynthesis. We now report the chromosomal localization of the threeHASgenes in human and in mouse. The genes localized to three different positions within both the human and the mouse genomes.HAS1was localized to the human chromosome 19q13.3–q13.4 boundary andHas1to mouse Chr 17.HAS2was localized to human chromosome 8q24.12 andHas2to mouse Chr 15.HAS3was localized to human chromosome 16q22.1 andHas3to mouse Chr 8. The map position forHAS1reinforces the recently reported relationship between a small region of human chromosome 19q and proximal mouse chromosome 17.HAS2mapped outside the predicted critical region delineated for the Langer–Giedion syndrome and can thus be excluded as a candidate gene for this genetic syndrome.     

Completion of the physical map of Xq28: the location of the gene for L1CAM on the human X Chromosome

The gene for the neural cell adhesion molecule L1 (L1CAM) has been shown to be located close to the color vision pigment genes in mouse and man. This location has been confirmed by a number of different mapping strategies in both species. With pulsed field gel electrophoresis it has been proposed that L1CAM lies between the RCP, GCP, and GDX, G6PD loci. We report here a reinterpretation of the location of this gene, based on the physical linkage of L1CAM to the more proximal locus DXS15. This places L1CAM between this marker and the color vision genes (RCP, GCP), a region very dense in CpG islands, expected to contain a large fraction of the disease genes assigned to the Xq28 region. In combination with the physical mapping data on Xq28 described previously, this closes the last remaining gap in the map of the Xq27–Xq28 region. This removes the last contradiction between the maps of this region in the genomes of man and mouse, and confirms the close similarity of order and distances of markers between these organisms. Offprint requests to: C.M. Disteche     

Nucleotide Sequencing Analysis of the 146-Kilobase Segment around theIkBLandMICAGenes at the Centromeric End of the HLA Class I Region

To elucidate the complete gene structure and to identify new genes involved in the development ofHLAclass I antigen-associated diseases in the class I region of the human major histocompatibility complex on chromosome 6, a YAC clone (745D12) covering the 146-kb segment around theIkBLandMICAloci was isolated from a YAC library constructed from the B-cell line, BOLETH. A physical map of this region was constructed by isolation of overlapping cosmid clones derived from 745D12. Of these, five contiguous cosmids were chosen for DNA sequencing by the shotgun strategy to give a single contig of 146,601 bp from 2.8 kb telomeric of theIkBLgene to exon 6 ofMICA.This region was confirmed to contain five known genes,IkBL, BAT1, MICB, P5-1,andHLA-X(class I fragment), from centromere to telomere, and their exon–intron organizations were determined. The3.8-1homologue gene (3.8-1-hom) showing 99.7% identity with the3.8-1cDNA clone, which was originally isolated using the 3.8-kbEcoRI fragment between theHLA-54/Hand theHLA-Ggenes, was detected betweenMICAandMICBand was suggested to represent the cognate3.8-1genomic sequence from which the cDNA clone was derived. No evidence for the presence of expressed new genes could be obtained in this region by homology and EST searches or coding and exon prediction analyses. One TA microsatellite repeat spanning 2545 bases with as many as 913 repetitions was found on the centromeric side of theMICAgene and was indicated to be a potential hot spot for genetic recombination. The two segments of approximately 35 kb upstream of theMICAandMICBgenes showed high sequence homology (about 85%) to each other, suggesting that segmental genome duplication including theMICAandMICBgenes must have occurred during the evolution of the humanMHC.     

Chromosomal Mapping ofTmp(Emp1),Xmp(Emp2), andYmp(Emp3), Genes Encoding Membrane Proteins Related toPmp22

We have recently characterized a novel mammalian gene family, encoding membrane glycoproteins with four trans-membrane domains. This gene family includes the previously studiedPMP22,which is involved in the Charcot–Marie–Tooth neuropathy, and three novel genes:TMP, XMP,andYMP(HGMW-approved symbolsEMP1, EMP2andEMP3,respectively). TheTmp(tumor-associated membrane protein) gene was isolated from a c-mycinduced mouse brain tumor and is expressed in several highly proliferative cell types. We have now isolated cDNAs of the mouseXmpandYmpgenes and determined the chromosomal localization of mouseTmp, Xmp,andYmp. Tmpwas mapped to mouse chromosome 6,Xmpwas mapped to chromosome 16, andYmpwas mapped to chromosome 7.TmpandYmpmap to paralogous chromosomal regions, whereasXmpmaps to a chromosomal region that is putatively paralogous to a region on chromosome 11, to whichPmp22was previously mapped. These data suggest that this family of membrane glycoproteins evolved as a result of chromosomal duplications.     

Localization of Human Flavin-Containing Monooxygenase GenesFMO2andFMO5to Chromosome 1q

The human flavin-containing monooxygenase (FMO) gene family comprises at least five distinct members (FMO1toFMO5) that code for enzymes responsible for the oxidation of a wide variety of soft nucleophilic substrates, including drugs and environmental pollutants. Three of these genes (FMO1, FMO3,andFMO4) have previously been localized to human chromosome 1q, raising the possibility that the entire gene family is clustered in this chromosomal region. Analysis by polymerase chain reaction of DNA isolated from a panel of human–rodent somatic cell hybrids demonstrates that the two remaining identified members of theFMOgene family,FMO2andFMO5,also are located on chromosome 1q.     

YAC Contigs of theRab1andwobbler(wr) Spinal Muscular Atrophy Gene Region on Proximal Mouse Chromosome 11 and of the Homologous Region on Human Chromosome 2p

Despite rapid progress in the physical characterization of murine and human genomes, little molecular information is available on certain regions, e.g., proximal mouse chromosome 11 (Chr 11) and human chromosome 2p (Chr 2p). We have localized thewobblerspinal atrophy genewrto proximal mouse Chr 11, tightly linked toRab1,a gene coding for a small GTP-binding protein, andGlns-ps1,an intronless pseudogene of the glutamine synthetase gene. We have now used these markers to construct a 1.3-Mb yeast artificial chromosome (YAC) contig of theRab1region on mouse Chr 11. Four YAC clones isolated from two independent YAC libraries were characterized by rare-cutting analysis, fluorescencein situhybridization (FISH), and sequence-tagged site (STS) isolation and mapping.Rab1andGlns-ps1were found to be only 200 kb apart. A potential CpG island near a methylatedNarI site and a trapped exon,ETG1.1,were found between these loci, and a new STS,AHY1.1,was found over 250 kb fromRab1.Two overlapping YACs were identified that contained a 150-kb region of human Chr 2p, comprising theRAB1locus,AHY1.1,and the human homologue ofETG1.1,indicating a high degree of conservation of this region in the two species. We mappedAHY1.1and thus humanRAB1on Chr 2p13.4–p14 using somatic cell hybrids and a radiation hybrid panel, thus extending a known region of conserved synteny between mouse Chr 11 and human Chr 2p. Recently, the geneLMGMD2Bfor a human recessive neuromuscular disease, limb girdle muscular dystrophy type 2B, has been mapped to 2p13–p16. The conservation between the mouseRab1and humanRAB1regions will be helpful in identifying candidate genes for thewobblerspinal muscular atrophy and in clarifying a possible relationship betweenwrandLMGMD2B.     

A Novel Ribosomal S6-Kinase (RSK4; RPS6KA6) Is Commonly Deleted in Patients with Complex X-Linked Mental Retardation

Large deletions in Xq21 often are associated with contiguous gene syndromes consisting of X-linked deafness type 3 (DFN3), mental retardation (MRX), and choroideremia (CHM). The identification of deletions associated with classic CHM or DFN3 facilitated the positional cloning of the underlying genes, REP-1 and POU3F4, respectively, and enabled the positioning of the MRX gene in between these genes. Here, we report the cloning and characterization of a novel gene, ribosomal S6-kinase 4 (RSK4; HGMW-approved symbol RPS6KA6), which maps in the MRX critical region. RSK4 is completely deleted in eight patients with the contiguous gene syndrome including MRX, partially deleted in a patient with DFN3 and present in patients with an Xq21 deletion and normal intellectual abilities. RSK4 is most abundantly expressed in brain and kidney. The predicted protein of 746 amino acids shows a high level of homology to three previously isolated members of the human RSK family. RSK2 is involved in Coffin–Lowry syndrome and nonspecific MRX. The localization of RSK4 in the interval that is commonly deleted in mentally retarded males together with the high degree of amino acid identity with RSK2 suggests that RSK4 plays a role in normal neuronal development. Further mutation analyses in males with X-linked mental retardation must prove that RSK4 is indeed a novel MRX gene.     

Genomic organization of a mouse MHC class II region including theH2-M andLmp2 loci

The region encompassing theMa, Mb1, Mb2, andLmp2 genes of the mouse class II major histocompatibility complex (MHC) was sequenced. Since this region contains clusters of genes required for efficient class I and class II antigen presentation, it was interesting to search for putative additional genes in the 21 kilobase gap between theMb1 andLmp2 genes. Computer predictions of coding regions and CpG islands, exon trapping experiments, and cross-species comparison with the corresponding human sequence indicate that no additional functional gene is present in that stretch. However, computer analysis revealed the possible existence of an alternative 3 exon forMb1. Except for the fact that the mouse MHC contains twoMb genes, the genomic organization of theH2-M loci was found to be almost identical to the organization of the humanHLA-DM genes. The promoter regions of theMa andMb genes also resemble classical class II promoters, containing typical S, X, and Y boxes. Like the human genes, the threeH2-M genes displayed very limited polymorphism when we compared the cDNA sequences from six haplotypes. Finally, comparison ofDMB withMb1 andMb2, both at the genomic level and in their coding regions, suggests that theMb gene was recently duplicated, probably only in certain rodents.     

Frequent MAGE Mutations in Human Melanoma

Background

Cancer/testis (CT) genes are expressed only in the germ line and certain tumors and are most frequently located on the X-chromosome (the CT-X genes). Amongst the best studied CT-X genes are those encoding several MAGE protein families. The function of MAGE proteins is not well understood, but several have been shown to potentially influence the tumorigenic phenotype.

Methodology/Principal Findings

We undertook a mutational analysis of coding regions of four CT-X MAGE genes, MAGEA1, MAGEA4, MAGEC1, MAGEC2 and the ubiquitously expressed MAGEE1 in human melanoma samples. We first examined cell lines established from tumors and matching blood samples from 27 melanoma patients. We found that melanoma cell lines from 37% of patients contained at least one mutated MAGE gene. The frequency of mutations in the coding regions of individual MAGE genes varied from 3.7% for MAGEA1 and MAGEA4 to 14.8% for MAGEC2. We also examined 111 fresh melanoma samples collected from 86 patients. In this case, samples from 32% of the patients exhibited mutations in one or more MAGE genes with the frequency of mutations in individual MAGE genes ranging from 6% in MAGEA1 to 16% in MAGEC1.

Significance

These results demonstrate for the first time that the MAGE gene family is frequently mutated in melanoma.     

Chromosomal location and molecular mapping of a tan spot resistance gene in the winter wheat cultivar Red Chief

The winter wheat cultivar Red Chief has been identified as the wheat cultivar most resistant toPyrenophora tritici-repentis (Ptr). This study was undertaken to determine the inheritance, chromosomal location and molecular mapping of a tan spot resistance gene in Red Chief. χ² analysis of the F₂ segregation data of the hybrids between 21 monosomic lines of the susceptible wheat cultivar Chinese Spring and the resistant cultivar Red Chief revealed that tan spot resistance in cv. Red Chief is controlled by a single recessive gene located on chromosome 3A. Linkage analysis using SSR markers in the Red Chief/Chinese Spring F2 population showed that thetsr4 gene is clustered in the region aroundXgwm2a, on the short arm of chromosome 3A. This marker has also been identified as the closest marker to thetsr3 locus on chromosome 3D in synthetic wheat lines. Validation analysis of this marker for thetsr3 andtsr4 genes using 28 resistant and 6 susceptible genotypes indicated that the 120 bp allele (thetsr3 gene) specific fragment was observed in 11 resistant genotypes, including the three synthetic lines XX41, XX45 and XX110, while the 130 bp allele was amplified only in cv. Red Chief and Dashen.Xgwm2a can be used to trace the presence of the target gene in successive backcross generations and pyramiding of thetsr3 &tsr4 genes into a commonly grown and adaptable cultivar.