Your search keyword '"Teresa Esposito"' showing total 4 results

1. χ/Autosomal Translocations in the χq Critical Region Associated with Premature Ovarian Failure Fall within and outside Genes

Author

David Schlessinger, Teresa Esposito, Annalisa Scardovi, Mariano Rocchi, Antonino Forabosco, Ramaiah Nagaraja, Paul Waeltz, Luisa Herrera, and Steven Mumm

Subjects

Genetic Markers, Genetics, X Chromosome, Autosome, Models, Genetic, Breakpoint, Chromosome Breakage, Chromosomal translocation, Primary Ovarian Insufficiency, Biology, medicine.disease, Translocation, Genetic, Premature ovarian failure, Sequence-tagged site, chemistry.chemical_compound, chemistry, medicine, Humans, Female, Chromosomes, Artificial, Yeast, Gene, Transcription factor, DNA, Sequence Tagged Sites

Abstract

Premature ovarian failure curtails female reproductive life and is often linked to balanced Xq/autosomal translocations in a critical region. We mapped regions around translocations at the edges of this zone (one in Xq13.3, two in Xq26) in large-insert clones and analyzed their sequence. One Xq26 region is extensively transcribed and, in agreement with a recent independent analysis, the breakpoint interrupts a gene that encodes a widely expressed peptidase. In contrast 430 kb around the second Xq26 breakpoint has no putative or detected gene content. In 260 kb around the Xq13 translocation, the breakpoint falls among a cluster of repetitive elements at least 59 kb from the only detected gene (a rarely expressed T-box family transcription factor). We discuss our results in relation to models that ascribe premature ovarian failure to interruption of ovarian genes or to a failure of interactions involving DNA of the critical region during follicle development.

Published

2001

2. YAC Contig Organization and CpG Island Analysis in Xq28

Author

Teresa Esposito, Giovanna Romano, Rolland Reinbold, Amelia Casamassimi, Michele D'Urso, Ciro Campanile, Arturo Lania, Vittorio Cappa, Sandra Johnson, Annemarie Poustka, David Schlessinger, Giuseppe Palmieri, and Alfredo Ciccodicola

Subjects

Genetics, congenital, hereditary, and neonatal diseases and abnormalities, GC Rich Sequence, X Chromosome, Contig, DNA–DNA hybridization, Restriction Mapping, Chromosome Mapping, Locus (genetics), Biology, Xq28, Restriction enzyme, CpG site, Gene mapping, Humans, Chromosomes, Artificial, Yeast, Dinucleoside Phosphates

Abstract

One hundred nineteen YACs were assembled into 6 contigs spanning about 7.1 Mb of Xq28. The contigs were formatted with 65 STSs and 136 hybridization probes and were extensive enough to be aligned and oriented by published genetic linkage and somatic cell hybrid panel data. Selected YACs from the entire region were mapped with five rare-cutter restriction enzymes to infer the position of putative CpG islands indicative of gene locations; 48 such sites were identified by the near-coincidence of at least three rare-cutter sites. The analysis defined three subregions of Xq28: 4 Mb of moderate GC and CpG island content from the Xq27 border through the GABRA locus; 1.5 to 2 Mb, extending to the G6PD gene, that is variably and poorly cloned, but contains a high concentration of CpG islands and GC; and about 1.5 Mb between G6PD and the telomere, which is generally low in CpG and GC levels, including a subtelomeric DNA region that shows extensive homology to Yq DNA.

Published

1994

3. Physical and genetic characterization reveals a pseudogene, an evolutionary junction, and unstable loci in distal Xq28

Author

Michele D'Urso, Sue Kenwrick, Penelope E. Bonnen, Annemarie Poustka, Nina S. Heiss, David L. Nelson, Hayley Woffendin, Teresa Esposito, Takanori Yamagata, Tiziana Bardaro, and Swaroop Aradhya

Subjects

Genetics, X Chromosome, Positional cloning, Contig, Pseudogene, Molecular Sequence Data, Chromosome Mapping, Sequence Homology, Sequence Analysis, DNA, Biology, Polymorphism, Single Nucleotide, Linkage Disequilibrium, Xq28, Evolution, Molecular, Mice, Gene mapping, Haplotypes, Molecular evolution, Animals, Humans, X chromosome, Pseudogenes, Synteny

Abstract

A large portion of human Xq28 has been completely characterized but the interval between G6PD and Xqter has remained poorly understood. Because of a lack of stable, high-density clone coverage in this region, we constructed a 1.6-Mb bacterial and P1 artificial chromosome (BAC and PAC, respectively) contig to expedite mapping, structural and evolutionary analysis, and sequencing. The contig helped to reposition previously mismapped genes and to characterize the XAP135 pseudogene near the int22h-2 repeat. BAC clones containing the distal int22h repeats also demonstrated spontaneous rearrangements and sparse coverage, which suggested that they were unstable. Because the int22h repeats are involved in genetic diseases, we examined them in great apes to see if they have always been unstable. Differences in copy number among the apes, due to duplications and deletions, indicated that they have been unstable throughout their evolution. Taking another approach toward understanding the genomic nature of distal Xq28, we examined the homologous mouse region and found an evolutionary junction near the distal int22h loci that separated the human distal Xq28 region into two segments on the mouse X chromosome. Finally, haplotype analysis showed that a segment within Xq28 has resisted excessive interchromosomal exchange through great ape evolution, potentially accounting for the linkage disequilibrium recently reported in this region. Collectively, these data highlight some interesting features of the genomic sequence in Xq28 and will be useful for positional cloning efforts, mouse mutagenesis studies, and further evolutionary analyses.

Published

2002

4. Human protein kinase C Iota gene (PRKCI) is closely linked to the BTK gene in Xq21.3

Author

Alfredo Ciccodicola, Carmela Jones, Carmela Migliaccio, Michele D'Urso, Maurizio D'Esposito, David Schlessinger, Richard Mazzarella, Teresa Esposito, Alessandro Arcucci, Mazzarella, R., Ciccodicola, A., Esposito, T., Arcucci, Alessandro, Migliaccio, C., Jones, C., Schlessinger, D., D'Urso, M., and D'Esposito, M.

Subjects

Genetics, Expressed sequence tag, DNA, Complementary, X Chromosome, biology, Contig, Genetic Linkage, Molecular Sequence Data, food and beverages, Chromosome Mapping, Gene mutation, Protein-Tyrosine Kinases, Isoenzymes, genomic DNA, Gene mapping, biology.protein, Agammaglobulinaemia Tyrosine Kinase, Bruton's tyrosine kinase, Humans, Gene, X chromosome, Protein Kinase C

Abstract

The human X chromosome contains many disease loci, but only a small number of X-linked genes have been cloned and characterized. One approach to finding genes in genomic DNA uses partial sequencing of random cDNAs to develop {open_quotes}expressed sequence tags{close_quotes} (ESTs). Many authors have recently reported chromosomal localization of such ESTs using hybrid panels. Twenty ESTs specific for the X chromosome have been localized to defined regions with somatic cell hybrids, and 12 of them have been physically linked to markers that detect polymorphisms. One of these ESTs, EST02087, was physically linked in a 650-kb contig to the GLA ({alpha}-galactosidase) gene involved in Fabry disease. A comparison of this contig with a 7.5-Mb YAC contig indicated that this gene is also within 250 kb of the src-like protein-tyrosine kinase BTK (X-linked agammaglobulinemia protein-tyrosine kinase) gene in Xq21.3. 14 refs., 1 fig.

Published

1995