Your search keyword '"Patricia C M O'Brien"' showing total 4 results

1. Chromosome painting between human and lorisiform prosimians: Evidence for the HSA 7/16 synteny in the primate ancestral karyotype

Author

Beiyuan Fu, Wenhui Nie, Malcolm A. Ferguson-Smith, Terence J. Robinson, Jinhuan Wang, Patricia C. M. O’Brien, Weiting Su, and Fengtang Yang

Subjects

Genetics, biology, Galago, Chromosome, Karyotype, biology.organism_classification, Synteny, Chromosomes, Chromosome Painting, Evolution, Molecular, Lorisidae, Phylogenesis, Phylogenetics, Homo sapiens, Karyotyping, Anthropology, biology.animal, Animals, Chromosomes, Human, Humans, Primate, Anatomy

Abstract

Multidirectional chromosome painting with probes derived from flow-sorted chromosomes of humans (Homo sapiens, HSA, 2n = 46) and galagos (Galago moholi, GMO, 2n = 38) allowed us to map evolutionarily conserved chromosomal segments among humans, galagos, and slow lorises (Nycticebus coucang, NCO, 2n = 50). In total, the 22 human autosomal painting probes detected 40 homologous chromosomal segments in the slow loris genome. The genome of the slow loris contains 16 sytenic associations of human homologues. The ancient syntenic associations of human chromosomes such as HSA 3/21, 7/16, 12/22 (twice), and 14/15, reported in most mammalian species, were also present in the slow loris genome. Six associations (HSA 1a/19a, 2a/12a, 6a/14b, 7a/12c, 9/15b, and 10a/19b) were shared by the slow loris and galago. Five associations (HSA 1b/6b, 4a/5a, 11b/15a, 12b/19b, and 15b/16b) were unique to the slow loris. In contrast, 30 homologous chromosome segments were identified in the slow loris genome when using galago chromosome painting probes. The data showed that the karyotypic differences between these two species were mainly due to Robertsonian translocations. Reverse painting, using galago painting probes onto human chromosomes, confirmed most of the chromosome homologies between humans and galagos established previously, and documented the HSA 7/16 association in galagos, which was not reported previously. The presence of the HSA 7/16 association in the slow loris and galago suggests that the 7/16 association is an ancestral synteny for primates. Based on our results and the published homology maps between humans and other primate species, we propose an ancestral karyotype (2n = 60) for lorisiform primates.

Published

2006

2. Defining the breakpoints of proximal chromosome 14q rearrangements in nine patients using flow-sorted chromosomes

Author

James R. Lupski, Malcolm A. Ferguson-Smith, Deepak Kamnasaran, Paola Grammatico, Diane W. Cox, Patricia C. M. O’Brien, Oliver Quarrell, and Simone Schuffenhauer

Subjects

Male, Marker chromosome, Biology, Translocation, Genetic, Chromosome 15, Fatal Outcome, Chromosome regions, Humans, Child, Genetics (clinical), Chromosome 12, Chromosomes, Human, Pair 14, Family Health, Genetics, Chromosome 7 (human), Chromosome Mapping, Infant, Chromosome Breakage, Flow Cytometry, Molecular biology, Chromosome 17 (human), Child, Preschool, Female, Chromosome Deletion, Chromosome 21, Chromosome 22, Microsatellite Repeats

Abstract

The breakpoints of deletions and translocations in the proximal chromosome 14q region were defined in nine patients, four of whom have not been reported previously. The aberrant chromosomes were isolated by flow cytometry and used to map the chromosome 14 deletion or translocation breakpoints. The parental origins of deletions were ascertained as paternal in five cases and maternal in one. With the draft genomic sequence for human chromosome 14 available, gene searches were performed on selected intervals of the 14q11.2-q21 region to identify candidate genes for the observed phenotype in some of those affected. Gain of function of the gene PAX9 on chromosome 14 is a possible candidate for a t(14;18) patient affected with mesomelic bone dysplasia. Furthermore, a compilation of other human chromosome 14q proximal deletion and translocation cases was obtained from a search on cytogenetic databases. These findings suggest a locus for myelofibrosis at chromosome 14q13. This study contributes to useful information for identifying disease genes in this region.

Published

2001

3. Cross-species color banding in ten cases of myeloid malignancies with complex karyotypes

Author

Christine J. Harrison, Patricia C. M. O’Brien, Tina Butler, Kan-Luk Cheung, Malcolm A. Ferguson-Smith, Brian J. Hennessy, H. Grant Prentice, and Fengtang Yang

Subjects

Genetics, Cancer Research, Myeloid, medicine.diagnostic_test, Colour banding, Karyotype, Biology, Patient management, medicine.anatomical_structure, Chromosome 3, medicine, Homologous chromosome, Animal species, Fluorescence in situ hybridization

Abstract

Cross-species color banding is a multiple-color fluorescence in situ hybridization (FISH) technique using probes developed from other animal species. Hybridization to human metaphases produces color banding patterns specific for each homologous chromosome pair. The technique has been evaluated in a complementary manner with G-banding and chromosome painting in a series of 10 myeloid malignancies with complex or unresolved karyotypes. Color banding detected the majority of chromosomal abnormalities, which had been identified by G-banding and in each case revealed chromosomal changes that G-banding had not identified. Painting was necessary to confirm these abnormalities due to the limitation of only seven colors in the color-banded karyotype. At the same time, painting fortuitously uncovered cryptic abnormalities in 6 of 10 cases that had not been detected by color banding. Insertions were visible by painting only. This study has demonstrated that in the analysis of complex karyotypes, the application of color banding revealed the involvement of the long arm of chromosome 3, indicating a poor risk, in two cases not identified by G-banding. Therefore, these techniques applied together have revealed cryptic chromosomal abnormalities with prognostic significance, which in some cases may have implications for patient management.

Published

2000

4. Cross-species colour segmenting: A novel tool in human karyotype analysis

Author

Johannes Wienberg, Malcolm A. Ferguson-Smith, Patricia C. M. O’Brien, and Stefan Müller

Subjects

Genetics, medicine.diagnostic_test, Hybridization probe, Biophysics, Chromosome, Karyotype, Cell Biology, Hematology, Biology, Hylobates concolor, Pathology and Forensic Medicine, Flow sorting, Endocrinology, medicine, Homologous chromosome, %22">Fish , Fluorescence in situ hybridization

Abstract

We used fluorescence in situ hybridization (FISH) with DNA probes derived from bivariate fluorescence activated flow sorting of primate chromosomes. In cases where human and primate karyotypes differ by chromosome rearrangements, reverse painting of primate probes resulted in a subregional delineation of the human homologous chromosomes. Probes were used from two gibbon species (Hylobates concolor and H. syndactylus) which both showed highly rearranged karyotypes. Hybridization of human chromosomes with painting probes derived from both gibbons showed that, with the exception of human chromosomes 15, 18, 21, 22 and the sex chromosomes, each chromosome was differentiated in at least two and up to six segments. These probes have been used in the analysis of various cases of constitutional chromosomal rearrangements in human pathology including complex intrachromosomal rearrangements. They were also used in a multi colour format (colour segmenting) to differentiate the entire human karyotype into 81 homologous coloured segments with probes derived from H. concolor, and 74 segments with probes derived from H. syndactylus. The addition of colours not only simplifies chromosome identification compared to the analysis of classical banding based on grey values, but colour segmenting also provides simple coloured landmarks for further fine analysis by classical banding. Cytometry 33:445–452, 1998. © 1998 Wiley-Liss, Inc.

Published

1998