Recognition by human Vγ9/Vδ2 T cells of melanoma cells upon fusion with Daudi cells

 Daudi Burkitt’s lymphoma cells, unlike other tumor cell lines, stimulate human T cells coexpressing the variable (V) region genes TCRG-V9 and V TCRD-V2 to proliferate and secrete lymphokines. Hybrids, derived by the fusion of Daudi cells with the human melanoma cell line MZ2-MEL 2.2, retain the morphology of melanoma cells. Unlike the parental melanoma cell line, these Daudi × MZ2-MEL 2.2 hybrids stimulate secretion of tumor necrosis factor (TNF) and granulocyte/macrophage colony stimulating factor (GM-CSF) by CD4-positive Vγ9/Vδ2 T-cell clones. Whereas the stimulator phenotype of Daudi cells behaves as a dominant trait in Daudi × melanoma hybrids, the expression of B-cell differentiation markers is suppressed. Thus, the γ/δ T-cell ligand expressed by Daudi cells behaves as a dominant tumor antigen in Daudi × melanoma hybrids and is unrelated to the differentiated B-cell phenotype. Dominant expression of the Daudi ligand for human Vγ9/Vδ2 T cells in these hybrids may provide a basis for defining the stimulatory principle at the molecular level. Received: 2 May 1996 / Revised: 15 July 1996     

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.     

Tandem repeats modify the structure of the canine CD1D gene

Among the CD1 proteins that present lipid antigens to T cells, CD1d is the only one that stimulates a population of T cells with an invariant T‐cell receptor known as NKT cells. Sequencing of a 722 nucleotide gap in the dog (Canis lupus familiaris) genome revealed that the canine CD1D gene lacks a sequence homologous to exon 2 of human CD1D, coding for the start codon and signal peptide. Also, the canine CD1D gene contains three different short tandem repeats that disrupt the expected gene structure. Because canine CD1D cDNA lacks sequences homologous to human exon 2 and 3, the functionality of canine CD1d protein may be affected, and this could have consequences for the development and activation of canine NKT cells.     

Transfection and expression of a gene coding for a human melanoma antigen recognized by autologous cytolytic T lymphocytes

Human melanoma line MZ2-MEL expresses several antigens recognized by autologous cytolytic T lymphocytes (CTL). As a first step towards the cloning of the gene coding for one of these antigens, we tried to obtain transfectants expressing the antigen. The DNA recipient cell was a variant of MZ2-MEL which had been selected with a CTL clone for the loss of antigen E. It was cotransfected with genomic DNA of the original melanoma line and with selective plasmid pSVtkneo. Geneticin-resistant transfectants were obtained at a frequency of 2 × 10^–4. These transfectants were then screened for their ability to stimulate the production of tumor necrosis factor by the anti-E CTL clone. One transfectant expressing antigen E was identified among 70 000 drug-resistant transfectants. Its sensitivity to lysis by the anti-E CTL was equal to that of the original melanoma cell line. When this transfectant was submitted to immunoselection with the anti-E CTL clone, the resulting antigen-loss variants were found to have lost several of the transfected pSVtkneo sequences. This indicated that the gene coding for the antigen had been integrated in the vicinity of pSVtkneo sequences, as expected for cotransfected DNA. Address correspondence and offprint requests to: T. Boon.     

Cytolytic T lymphocytes recognize an antigen encoded by MAGE-A10 on a human melanoma.

From melanoma patient LB1751, cytolytic T lymphocytes (CTL) were generated that lysed specifically autologous tumor cells. To establish whether these CTL recognized one of the Ags that had previously been defined, a CTL clone was stimulated with cells expressing various MAGE genes. It produced TNF upon stimulation with target cells expressing MAGE-A10. The Ag was found to be nonapeptide GLYDGMEHL (codons 254-262), which is presented by HLA-A2.1. This is the first report on the generation of anti-MAGE CTL by autologous mixed lymphocyte-tumor cell culture (MLTC) from a melanoma patient other than patient MZ2, from whom the first MAGE gene was identified. MAGE genes are expressed in many tumors but not by normal tissues except male germline cells and placenta, which do not express HLA molecules. Therefore, the identification of an antigenic peptide derived from MAGE-A10 adds to the repertoire of tumor-specific shared Ags available for anti-tumoral vaccination trials.     

Characterization of the horse (<Emphasis Type="Italic">Equus caballus</Emphasis>)<Emphasis Type="Italic"> IGHA</Emphasis> gene

Nucleotide sequences of the immunoglobulin constant heavy chain genes of the horse have been described for IGHM, IGHG and IGHE genes, but not for IGHA. Here, we provide the nucleotide sequence of the genomic IGHA gene of the horse (Equus caballus), including its secretion region and the transmembrane exon. The equine IGHA gene shows the typical structure of a mammalian IGHA gene, with only three exons, separated by two introns of similar size. The hinge exon is located at the 5 end of the CH2 exon and encodes a hinge region of 11 amino acids, which contains five proline residues. The coding nucleotide sequence of the secreted form of the equine IGHA gene shares around 72% identity with the human IGHA1 and IGHA2 genes, as well as the bovine, ovine, porcine and canine IGHA genes, without distinct preference for any of these species. The same species also cluster together in a phylogenetic tree of the IGHA coding regions of various mammals, whereas rodent, rabbit, marsupial and monotreme IGHA genes each build a separate cluster.The nucleotide sequences reported in this paper have been assigned the EMBL/GenBank accession numbers AY247966 and AY351982     

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.     

A copy of exon 3-intron 3 from the barley aleurain gene is present on chromosome 2

A genomic clone fromHordeum vulgare L. cv. Himalaya contains 700 bp of DNA that is homologous with a high degree of nucleotide sequence similarity to exon 3-intron 3 from the gene for the thiol protease, aleurain. Genomic Southern blot mapping data indicate that this clone in phage had not undergone rearrangement, and no other sequences homologous to aleurain are present on it. Although exon 3 in aleurain encodes the polypeptide region cleaved during proteolytic processing of the proenzyme to its mature form, we do not know if the copy is expressed in some other protein. We have mapped the aleurain gene to chromosome 1, and this copy of exon 3-intron 3 to chromosome 2.     

The Human Prohibitin (PHB) Gene Family and Its Somatic Mutations in Human Tumors

Five cosmid clones, isolated by procedures to screen genomic libraries for homologous variants of the human prohibitin gene (PHB), were analyzed to determine their genomic structures. Four of these (PHBP1-4) were found to be processed pseudogenes, each located on a different chromosome from their counterparts on chromosome 17q21. The DNA sequence of one clone (PHBP1, on chromosome 6q25) shared a 91.3% identity at the nucleotide level with the cDNA of functional prohibitin. A large number of human tumors of the breast, ovary, liver, and lung were examined for somatic mutations in the PHB gene. Although mutations were observed in a few sporadic breast cancers, none were identified in any of the other cancers.     

Analysis of the sequence variations in the Mhc DRB1-like gene of the endangered Humboldt penguin (Spheniscus humboldti)

The Major Histocompatibility Complex (Mhc) genomic region of many vertebrates is known to contain at least one highly polymorphic class II gene that is homologous in sequence to one or other of the human Mhc DRB1 class II genes. The diversity of the avian Mhc class II gene sequences have been extensively studied in chickens, quails, and some songbirds, but have been largely ignored in the oceanic birds, including the flightless penguins. We have previously reported that several penguin species have a high degree of polymorphism on exon 2 of the Mhc class II DRB1-like gene. In this study, we present for the first time the complete nucleotide sequences of exon 2, intron 2, and exon 3 of the DRB1-like gene of 20 Humboldt penguins, a species that is presently vulnerable to the dangers of extinction. The Humboldt DRB1-like nucleotide and amino acid sequences reveal at least eight unique alleles. Phylogenetic analysis of all the available avian DRB-like sequences showed that, of five penguin species and nine other bird species, the sequences of the Humboldt penguins grouped most closely to the Little penguin and the mallard, respectively. The present analysis confirms that the sequence variations of the Mhc class II gene, DRB1, are useful for discriminating among individuals within the same penguin population as well those within different penguin population groups and species.The nucleotide sequence and amino acid sequence data reported in this paper have been submitted to the DDBJ database and have been assigned the accession numbers AB088371–AB088374, AB089199, AB154393–AB154399, and AB162144.     

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 peptide encoded by the human MAGE3 gene and presented by HLA-1344 induces cytolytic T lymphocytes that recognize tumor cells expressing MAGE3

The humanMAGE3 gene is expressed in a significant proportion of tumors of various histological types, but is silent in normal adult tissues other than testis and placenta. Antigens encoded byMAGE3 may therefore be useful targets for specific antitumor immunization. Two antigenic peptides encoded by theMAGE3 gene have been reported previously. One is presented to cytolytic T lymphocytes (CTL) by HLA-A1, the other by HLA-A2 molecules. Here we show that MAGE3 also codes for a peptide that is presented to CTL by HLA-1344.MAGE3 peptides containing the HLA-1344 peptide binding motif were synthesized. Peptide MEVDPIGHLY, which showed the strongest binding to HLA-1344, was used to stimulate blood T lymphocytes from normal HLA-1344 donors. CTL clones were obtained that recognized not only HLA-B44 cells sensitized with the peptide, but also HLA-B44 tumor cell lines expressingMAGE3. The proportion of metastatic melanomas expressing theMAGE3/HLA-1344 antigen should amount to approximately 17% in the Caucasian population, since 24% of individuals carry theHLA-B44 allele and 76% of these tumors express MAGE3.     

The nucleotide sequence and evolution of ovine MHC class II B genes: DQB and DRB

The nucleotide sequences of one Ovar-DQB gene, excluding exon 1 and parts of the introns, and one Ovar-DRB pseudogene are presented. The structure of the Ovar-DQB gene is typical of a major histocompatibility complex (MHC) class II B gene and demonstrats considerable sequence similarity with that of humans including such characteristics as the less common polyadenylation signal, ATTAAA. The ovine sequence has a typical 5' acceptor splice signal for exon 5, thus potentially encoding a full length cytoplasmic tail. The Ovar-DRB gene identified in this study was found to be a pseudogene, lacking a defined exon 2 and containing premature termination codons in both exons 3 and 4. The 3' donor splice site of exon 3 is also atypical. A purine-pyrimidine microsatellite repeat, (dCdA)₁₅, in the 3' region of the pseudogene may be a hotspot for recombination within the ovine DR subregion.The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide sequence database and have been assigned the accession numbers M33306 and M33307. Address correspondence and offprint requests to: M. R. Brandon.     

The Heat-Shock Gene hsp83 of Drosophila auraria: Genomic Organization, Nucleotide Sequence, and Long Antiparallel Coupled ORFs (LAC ORFs)

The genomic organization of the hsp83 gene of Drosophila auraria, a far-eastern endemic species belonging to the montium subgroup of the melanogaster species group, is presented here. Based on in situ hybridization on polytene chromosomes, cDNA and genomic clone mapping, nucleotide sequencing, and genomic Southern analysis, hsp83 is shown to be present as a single-copy gene at locus 64B on the 3L chromosome arm in D. auraria. This gene is organized into two exons separated by a 929-bp intron. The first exon represents the mRNA leader sequence and is not translated, while the coding region, having a length of 2,151 bp, is solely included in the second exon. Nucleotide sequence comparisons of D. auraria hsp83 with homologous sequences from other organisms show high conservation of the coding region (88–92% identity) in the genus Drosophila, in addition to the conserved genomic organization of two-exons–one-intron, of comparable size and arrangement. A phylogenetic tree based on the protein sequences of homologous genes from representative organisms is in accord with the accredited phylogenetic position of D. auraria. In the hsp83 gene region, a second case of long antiparallel coupled open reading frames (LAC ORFs) for this species was found. The antiparallel to the hsp83 gene ORF is 1,554 bases long, while the two ORFs overlap has a size of 1,548 bp. The anti-hsp83 ORF does not show significant homology to any known gene sequences. In addition, no similar LAC ORF structures were found in homologous gene regions of other organisms. Received: 18 April 1997 / Accepted: 1 August 1997