Your search keyword '"V Fernández-Soria"' showing total 5 results

1. Lack of HLA-G soluble isoforms in Graves-Basedow thyrocytes and complete cDNA sequence of the HLA-G*01012 allele.

Author

Castro MJ, Morales P, Catálfamo M, Fernández-Soria V, Suárez B, Varela P, Pérez-Blas M, Alvarez M, Jaraquemada D, and Arnaiz-Villena A

Subjects

Alleles, Alternative Splicing, Cell Line, Cells, Cultured, DNA, DNA, Complementary, Graves Disease genetics, HLA Antigens chemistry, HLA Antigens genetics, HLA-G Antigens, Histocompatibility Antigens Class I chemistry, Histocompatibility Antigens Class I genetics, Humans, Molecular Sequence Data, RNA, Messenger metabolism, Thyroid Gland cytology, Graves Disease immunology, HLA Antigens analysis, Histocompatibility Antigens Class I analysis, Thyroid Gland immunology

Abstract

The presence of HLA-G mRNA has been studied in thyroid follicular cells from autoimmune patients with Graves' disease. Investigating the possible role of the expression of the HLA-G gene in tissue inflammation, we have found four of the six HLA-G mRNA isoforms described: G1, G2, G3 and G4, but not the soluble ones G5 and G6. Soluble G isoforms may be responsible for inducing tolerance and inflammation control and their absence in autoimmune thyroid follicular cells may induce failure of such control. In addition, the complete coding sequence of HLA-G*01012 has been obtained from thyrocytes and it shows only four synonymous changes with respect to the HLA-G*01011 allele; this further supports the existence of an evolutionary pressure for invariance on HLA-G genes.

Published

1998

2. Allelic diversity at the primate Mhc-G locus: exon 3 bears stop codons in all Cercopithecinae sequences.

Author

Castro MJ, Morales P, Fernández-Soria V, Suarez B, Recio MJ, Alvarez M, Martín-Villa M, and Arnaiz-Villena A

Subjects

Alleles, Animals, Base Sequence, Biological Evolution, Exons, HLA-G Antigens, Humans, Introns, Macaca genetics, Molecular Sequence Data, Pan troglodytes genetics, Phylogeny, Polymorphism, Genetic, Sequence Alignment, Sequence Homology, Nucleic Acid, Cercopithecinae genetics, HLA Antigens genetics, Histocompatibility Antigens Class I genetics, Major Histocompatibility Complex

Abstract

Twenty-seven major histocompatibility complex (Mhc)-G exon 2, exon 3, and exon 2 and 3 allelic sequences were obtained together with 12 different intron 2 sequences. Homo sapiens, Pan troglodytes, Pan paniscus, Gorilla gorilla, Pongo pygmaeus, Macaca fascicularis, Macaca mulatta, and Cercopithecus aethiops individuals were studied. Polymorphism does not follow the classical pattern of three hypervariable regions per domain and is found in all species studied; exon 3 (equivalent to the alpha 2 protein domain) shows stop codons in the Cercopithecinae group but not in the Pongidae and human groups. Dendrograms show that cotton top tamarin (Saguinus oedipus) Mhc-G sequences are closer to Homo sapiens and Pongidae than to Cercopithecinae, probably due to the stop codons existing at exon 3 of the latter. There is a clear trans-species evolution of allelism in Cercopithecinae and also in exon 2 of all the other apes studied, but a generation of allelism within each species may be present on exon 3 sequences. This discrepancy may be due to the preferential use of exon 2 over exon 3 at the mRNA splicing level within each species in order to obtain the appropriate functional G product. Mhc-G intron 2 shows conserved motifs in all species studied, particularly a 23 base pair deletion between positions 161 and 183 which is locus specific, and some of the invariant residues, important for peptide presentation, conserved in classical class I molecules from fish and reptiles to humans were not found in Mhc-G alleles; the intron 2 dendrogram also shows a particular pattern of allelism within each species. In summary, Mhc-G has substantial differences from other classical class I genes: polymorphism patterns, tissue distribution, gene structure, splicing variability, and probably an allelism variability within each species at exon 3. The G proteins may also be different. This indicates that the Mhc-G function may not be peptide presentation to the clonotypic T-cell receptor.

Published

1996

3. Allelic diversity at the primateMhc-G locus: Exon 3 bears stop codons in allCercophitecinae sequences

Author

M. José Recio, M. José Castro, Antonio Arnaiz-Villena, V Fernández-Soria, Miguel Alvarez, Pablo Morales, Manuel Martin-Villa, and Belen Suarez

Subjects

Pan troglodytes, Molecular Sequence Data, Immunology, Locus (genetics), Biology, Exon shuffling, Major Histocompatibility Complex, Exon, Exon trapping, Cercopithecinae, HLA Antigens, Sequence Homology, Nucleic Acid, Genetics, Animals, Humans, Gene, Alleles, Phylogeny, HLA-G Antigens, Polymorphism, Genetic, Base Sequence, Histocompatibility Antigens Class I, Intron, Exons, Biological Evolution, Introns, Stop codon, RNA splicing, Macaca, Sequence Alignment

Abstract

Twenty-seven major histocompatibility complex (Mhc)-G exon 2, exon 3, and exon 2 and 3 allelic sequences were obtained together with 12 different intron 2 sequences. Homo sapiens, Pan troglodytes, Pan paniscus, Gorilla gorilla, Pongo pygmaeus, Macaca fascicularis, Macaca mulatta, and Cercopithecus aethiops individuals were studied. Polymorphism does not follow the classical pattern of three hypervariable regions per domain and is found in all species studied; exon 3 (equivalent to the alpha 2 protein domain) shows stop codons in the Cercopithecinae group but not in the Pongidae and human groups. Dendrograms show that cotton top tamarin (Saguinus oedipus) Mhc-G sequences are closer to Homo sapiens and Pongidae than to Cercopithecinae, probably due to the stop codons existing at exon 3 of the latter. There is a clear trans-species evolution of allelism in Cercopithecinae and also in exon 2 of all the other apes studied, but a generation of allelism within each species may be present on exon 3 sequences. This discrepancy may be due to the preferential use of exon 2 over exon 3 at the mRNA splicing level within each species in order to obtain the appropriate functional G product. Mhc-G intron 2 shows conserved motifs in all species studied, particularly a 23 base pair deletion between positions 161 and 183 which is locus specific, and some of the invariant residues, important for peptide presentation, conserved in classical class I molecules from fish and reptiles to humans were not found in Mhc-G alleles; the intron 2 dendrogram also shows a particular pattern of allelism within each species. In summary, Mhc-G has substantial differences from other classical class I genes: polymorphism patterns, tissue distribution, gene structure, splicing variability, and probably an allelism variability within each species at exon 3. The G proteins may also be different. This indicates that the Mhc-G function may not be peptide presentation to the clonotypic T-cell receptor.

Published

1996

4. Lack of HLA-G soluble isoforms in Graves-Basedow thyrocytes and complete cDNA sequence of the HLA-G*01012 allele

Author

M J, Castro, P, Morales, M, Catálfamo, V, Fernández-Soria, B, Suárez, P, Varela, M, Pérez-Blas, M, Alvarez, D, Jaraquemada, and A, Arnaiz-Villena

Subjects

HLA-G Antigens, DNA, Complementary, Histocompatibility Antigens Class I, Molecular Sequence Data, Thyroid Gland, DNA, Graves Disease, Cell Line, Alternative Splicing, HLA Antigens, Humans, RNA, Messenger, Alleles, Cells, Cultured

Abstract

The presence of HLA-G mRNA has been studied in thyroid follicular cells from autoimmune patients with Graves' disease. Investigating the possible role of the expression of the HLA-G gene in tissue inflammation, we have found four of the six HLA-G mRNA isoforms described: G1, G2, G3 and G4, but not the soluble ones G5 and G6. Soluble G isoforms may be responsible for inducing tolerance and inflammation control and their absence in autoimmune thyroid follicular cells may induce failure of such control. In addition, the complete coding sequence of HLA-G*01012 has been obtained from thyrocytes and it shows only four synonymous changes with respect to the HLA-G*01011 allele; this further supports the existence of an evolutionary pressure for invariance on HLA-G genes.

Published

1998

5. Mhc-E polymorphism in Pongidae primates: the same allele is found in two different species

Author

Maria J. Recio, Mercedes Pérez-Blas, Nieves Diaz-Campos, V Fernández-Soria, Belen Suarez, P. Morales, Antonio Arnaiz-Villena, María Jesús Pena Castro, and Miguel Alvarez

Subjects

DNA, Complementary, Pan troglodytes, Immunology, Molecular Sequence Data, Cercopithecinae, Gorilla, Locus (genetics), Biochemistry, Major Histocompatibility Complex, Exon, Species Specificity, Phylogenetics, HLA Antigens, biology.animal, Pongo pygmaeus, Sequence Homology, Nucleic Acid, Genetics, Immunology and Allergy, Animals, Humans, Alleles, Phylogeny, Cell Line, Transformed, Gorilla gorilla, Polymorphism, Genetic, biology, Phylogenetic tree, Base Sequence, Histocompatibility Antigens Class I, Pongidae, Hominidae, General Medicine, Pan paniscus, biology.organism_classification

Abstract

Mhc-E intron 1, exon 2, intron 2, and exon 3 from pygmy chimpanzee (Pan paniscus), chimpanzee (Pan troglodytes), gorilla (Gorilla gorilla) and orangutan (Pongo pygmaeus) have been sequenced; six new Mhc-E alleles have been obtained but sequence changes are only placed either in introns or in synonymous exonic bases. One pygmy chimpanzee Mhc-E DNA sequence is identical to another sequence from chimpanzee; the fact that no variation is found also at the intronic level suggests that these two species of chimpanzee may have recently separated and/or that both of them might only represent subspecies. Mhc-E phylogenetic trees separate two evolutionary groups: Pongidae, including humans, and Cercopithecinae; this is also found by studying another non-classical class I gene, Mhc-G. The Mhc-E alleles' invariance at the protein level supports that strong selective forces are operating at the Mhc-E locus, as has also been found in both Cercopithecinae and humans. These allelic and evolutionary data suggest an altogether different functionality for HLA-E (and also HLA-G) compared with classical class I proteins: i.e., sending negative (tolerogenic) signals to NK and T cells.

Published

1998