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10 results on '"Guttmacher, A.E."'

4. Quantitative DNA pooling to increase the efficiency of linkage analysis in autosomal dominant disease

Author

University of Michigan, Ann Arbor, Mich., USA, US, University of Vermont College of Medicine, Burlington, Vt., USA, US, University of Ottawa Eye Institute, 501 Smyth Rd, Ottawa, Ontario, Canada K1H 8L6 Fax: +1-613-737-8836; e-mail: kdamji@ogh.on.ca, CA, Duke University, Durham, N.C., USA, US, Ann Arbor, Damji, K.F., Vance, J.M., Gallione, C.J., Marchuk, Douglas A., Allingham, R.R., Guttmacher, A.E., Speer, M.C., Pericak-Vance, M.A., Slotterbeck, B., Pasyk, Krystyna A., University of Michigan, Ann Arbor, Mich., USA, US, University of Vermont College of Medicine, Burlington, Vt., USA, US, University of Ottawa Eye Institute, 501 Smyth Rd, Ottawa, Ontario, Canada K1H 8L6 Fax: +1-613-737-8836; e-mail: kdamji@ogh.on.ca, CA, Duke University, Durham, N.C., USA, US, Ann Arbor, Damji, K.F., Vance, J.M., Gallione, C.J., Marchuk, Douglas A., Allingham, R.R., Guttmacher, A.E., Speer, M.C., Pericak-Vance, M.A., Slotterbeck, B., and Pasyk, Krystyna A.

Abstract

DNA pooling is an efficient method to rapidly perform genome-wide linkage scans in autosomal recessive diseases in inbred populations where affected individuals are likely to be homozygous for alleles near the disease gene locus. We wanted to examine whether this approach would detect linkage in autosomal dominant (AD) disorders where affected individuals may share one allele identical by descent at loci tightly linked to the disease. Two large outbred pedigrees in which the AD diseases familial venous malformation (FVM) and hereditary hemorrhagic telangiectasia (HHT1), linked to 9p and 9q, respectively, were investigated. Separate pools of DNA from affected (n = 21 for FVM and 17 for HHT1) and unaffected family members (n = 9 FVM and HHT1), and 25 unrelated population controls were established. Polymorphic markers spanning chromosome 9 at approximately 13.5-cM intervals were amplified using standard PCR. Allele quantitation was performed with a fluorimager. Visual inspection of allele intensities and frequency distributions suggested a shift in frequency of the most common allele in the affecteds lane when compared to control lanes for markers within 30 cM of the FVM and HHT1 loci. These subjective assessments were confirmed statistically by testing for the difference between two proportions (one-sided; P??? 0.05). When using population controls, the true-positive rates for FVM and HHT1 were 5/5 and 2/5 markers, respectively. False-positive rates for FVM and HHT1 were 3/9 and 2/9, respectively. In both AD diseases investigated, quantitative DNA pooling detected shifts in allele frequency, thus identifying areas of known linkage in most cases. The utility of this technique depends on the size of the pedigree, frequency of the disease-associated allele in the population, and the choice of appropriate controls. Although the false-positive rate appears to be high, this approach still serves to reduce the amount of overall genotyping by about 60%. DNA pooling merits

Published
2006

5. Molecular and clinical analyses of Greig cephalopolysyndactyly and Pallister-Hall syndromes: robust phenotype prediction from the type and position of GLI3 mutations.

Author

Johnston, J.J., Olivos-Glander, I., Killoran, C., Elson, E., Turner, J.T., Peters, K.F., Abbott, M.H., Aughton, D.J., Aylsworth, A.S., Bamshad, M., Booth, C., Curry, C.J., David, A., Dinulos, M.B., Flannery, D.B., Fox, M.A., Graham, J.M., Grange, D.K., Guttmacher, A.E., Hannibal, M.C., Henn, W., Hennekam, R.C.M., Holmes, L.B., Hoyme, H.E., Leppig, K.A., Lin, A.E., Macleod, P., Manchester, D.K., Marcelis, C.L.M., Mazzanti, L., McCann, E., McDonald, M.T., Mendelsohn, N.J., Moeschler, J.B., Moghaddam, B., Neri, G., Newbury-Ecob, R., Pagon, R.A., Phillips, J.A., Sadler, L.S., Stoler, J.M., Tilstra, D., Walsh Vockley, C.M., Zackai, E.H., Zadeh, T.M., Brueton, L., Black, G.C.M., Biesecker, L.G., Johnston, J.J., Olivos-Glander, I., Killoran, C., Elson, E., Turner, J.T., Peters, K.F., Abbott, M.H., Aughton, D.J., Aylsworth, A.S., Bamshad, M., Booth, C., Curry, C.J., David, A., Dinulos, M.B., Flannery, D.B., Fox, M.A., Graham, J.M., Grange, D.K., Guttmacher, A.E., Hannibal, M.C., Henn, W., Hennekam, R.C.M., Holmes, L.B., Hoyme, H.E., Leppig, K.A., Lin, A.E., Macleod, P., Manchester, D.K., Marcelis, C.L.M., Mazzanti, L., McCann, E., McDonald, M.T., Mendelsohn, N.J., Moeschler, J.B., Moghaddam, B., Neri, G., Newbury-Ecob, R., Pagon, R.A., Phillips, J.A., Sadler, L.S., Stoler, J.M., Tilstra, D., Walsh Vockley, C.M., Zackai, E.H., Zadeh, T.M., Brueton, L., Black, G.C.M., and Biesecker, L.G.

Abstract

Contains fulltext : 48832.pdf (publisher's version ) (Closed access), Mutations in the GLI3 zinc-finger transcription factor gene cause Greig cephalopolysyndactyly syndrome (GCPS) and Pallister-Hall syndrome (PHS), which are variable but distinct clinical entities. We hypothesized that GLI3 mutations that predict a truncated functional repressor protein cause PHS and that functional haploinsufficiency of GLI3 causes GCPS. To test these hypotheses, we screened patients with PHS and GCPS for GLI3 mutations. The patient group consisted of 135 individuals: 89 patients with GCPS and 46 patients with PHS. We detected 47 pathological mutations (among 60 probands); when these were combined with previously published mutations, two genotype-phenotype correlations were evident. First, GCPS was caused by many types of alterations, including translocations, large deletions, exonic deletions and duplications, small in-frame deletions, and missense, frameshift/nonsense, and splicing mutations. In contrast, PHS was caused only by frameshift/nonsense and splicing mutations. Second, among the frameshift/nonsense mutations, there was a clear genotype-phenotype correlation. Mutations in the first third of the gene (from open reading frame [ORF] nucleotides [nt] 1-1997) caused GCPS, and mutations in the second third of the gene (from ORF nt 1998-3481) caused primarily PHS. Surprisingly, there were 12 mutations in patients with GCPS in the 3' third of the gene (after ORF nt 3481), and no patients with PHS had mutations in this region. These results demonstrate a robust correlation of genotype and phenotype for GLI3 mutations and strongly support the hypothesis that these two allelic disorders have distinct modes of pathogenesis.

Published
2005

7. Mutations in the activin receptor–like kinase 1 gene in hereditary haemorrhagic telangiectasia type 2

Author

Johnson, D.W., primary, Berg, J.N., additional, Baldwin, M.A., additional, Gallione, C.J., additional, Marondel, I., additional, Yoon, S.-J., additional, Stenzel, T.T., additional, Speer, M., additional, Pericak-Vance, M.A., additional, Diamond, A., additional, Guttmacher, A.E., additional, Jackson, C.E., additional, Attisano, L., additional, Kucherlapati, R., additional, Porteous, M.E.M., additional, and Marchuk, D.A., additional

Published
1996
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8. Endoglin, a TGF-β binding protein of endothelial cells, is the gene for hereditary haemorrhagic telangiectasia type 1

Author

McAllister, K.A., primary, Grogg, K.M., additional, Johnson, D.W., additional, Gallione, C.J., additional, Baldwin, M.A., additional, Jackson, C.E., additional, Helmbold, E.A., additional, Markel, D.S., additional, McKinnon, W.C., additional, Murrel, J., additional, McCormick, M.K., additional, Pericak-Vance, M.A., additional, Heutink, P., additional, Oostra, B.A., additional, Haitjema, T., additional, Westerman, C.J.J., additional, Porteous, M.E., additional, Guttmacher, A.E., additional, Letarte, M., additional, and Marchuk, D.A., additional

Published
1994
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9. A disease locus for hereditary haemorrhagic telangiectasia maps to chromosome 9q33–34

Author

McDonald, M.T., primary, Papenberg, K.A., additional, Ghosh, S., additional, Glatfelter, A.A., additional, Biesecker, B.B., additional, Helmbold, E.A., additional, Markel, D.S., additional, Zolotor, A., additional, McKinnon, W.C., additional, Vanderstoep, J.L., additional, Jackson, C.E., additional, Iannuzzi, M., additional, Collins, F.S., additional, Boehnke, M., additional, Porteous, M.E., additional, Guttmacher, A.E., additional, and Marchuk, D.A., additional

Published
1994
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10. MOLECULAR AND CLINICAL ANALYSES OF GREIG CEPHALOPOLYSYNDACTYLY AND PALLISTER-HALL SYNDROMES: ROBUST PHENOTYPE PREDICTION FROM THE TYPE AND POSITION OF GLI3 MUTATIONS

Author

Arthur S. Aylsworth, Nancy J. Mendelsohn, Kathleen A. Leppig, Albert David, H. Eugene Hoyme, Carlo Marcelis, Louise Brueton, Joan M. Stoler, Elaine H. Zackai, Roberta A Pagon, Mary Beth Dinulos, Raoul C.M. Hennekam, David J. Aughton, Cynthia J. Curry, Billur Moghaddam, Jennifer J. Johnston, Marie T. McDonald, Kathryn F. Peters, Laura Mazzanti, Laurie S. Sadler, Carol Booth, Catherine Walsh Vockley, David Tilstra, Lewis B. Holmes, Touran M. Zadeh, Isabelle M. Olivos-Glander, John A. Phillips, Michael J. Bamshad, Angela E. Lin, David B. Flannery, Alan E. Guttmacher, Emma Elson, Leslie G. Biesecker, Christina Killoran, Graeme C.M. Black, Ruth Newbury-Ecob, Wolfram Henn, Patrick MacLeod, John M. Graham, John B. Moeschler, Emma McCann, Margaret H. Abbott, Michelle Fox, Giovanni Neri, Joyce T. Turner, Mark C. Hannibal, David K. Manchester, Dorothy K. Grange, Johnston J.J., Olivos-Glander I., Killoran C., Elson E., Turner J.T., Peters K.F., Abbott M.H., Aughton D.J., Aylsworth A.S., Bamshad M.J., Booth C., Curry C.J., David A., Dinulos M.B., Flannery D.B., Fox M.A., Graham J.M., Grange D.K., Guttmacher A.E., Hannibal M.C., Henn W., Hennekam R.C., Holmes L.B., Hoyme H.E., Leppig K.A., Lin A.E., Macleod P., Manchester D.K., Marcelis C., Mazzanti L., McCann E., McDonald M.T., Mendelsohn N.J., Moeschler J.B., Moghaddam B., Neri G., Newbury-Ecob R., Pagon R.A., Phillips J.A., Sadler L.S., Stoler J.M., Tilstra D., Walsh Vockley C.M., Zackai E.H., Zadeh T.M., Brueton L., Black G.C., Biesecker L.G., ANS - Amsterdam Neuroscience, APH - Amsterdam Public Health, Paediatric Genetics, and Faculteit der Geneeskunde

Subjects
Hamartoma, Nonsense mutation, Kruppel-Like Transcription Factors, Nerve Tissue Proteins, PALLISTER-HALL SYNDROME, Biology, medicine.disease_cause, Epiglottis, Frameshift mutation, Craniofacial Abnormalities, Genomic disorders and inherited multi-system disorders [IGMD 3], 03 medical and health sciences, 0302 clinical medicine, Genotype-phenotype distinction, Zinc Finger Protein Gli3, Genetics, medicine, Humans, Missense mutation, Abnormalities, Multiple, Genetics(clinical), Genetics (clinical), 030304 developmental biology, Greig cephalopolysyndactyly syndrome, 0303 health sciences, Mutation, Hypertelorism, GLI3 MUTATION, Zinc Fingers, Articles, Syndrome, medicine.disease, 3. Good health, GREIGCEPHALOPOLYSYNDACTYLY, DNA-Binding Proteins, Polydactyly, Phenotype, Genetic defects of metabolism [UMCN 5.1], Pallister–Hall syndrome, Syndactyly, Haploinsufficiency, Hypothalamic Diseases, 030217 neurology & neurosurgery, Transcription Factors
Abstract

Contains fulltext : 48832.pdf (Publisher’s version ) (Closed access) Mutations in the GLI3 zinc-finger transcription factor gene cause Greig cephalopolysyndactyly syndrome (GCPS) and Pallister-Hall syndrome (PHS), which are variable but distinct clinical entities. We hypothesized that GLI3 mutations that predict a truncated functional repressor protein cause PHS and that functional haploinsufficiency of GLI3 causes GCPS. To test these hypotheses, we screened patients with PHS and GCPS for GLI3 mutations. The patient group consisted of 135 individuals: 89 patients with GCPS and 46 patients with PHS. We detected 47 pathological mutations (among 60 probands); when these were combined with previously published mutations, two genotype-phenotype correlations were evident. First, GCPS was caused by many types of alterations, including translocations, large deletions, exonic deletions and duplications, small in-frame deletions, and missense, frameshift/nonsense, and splicing mutations. In contrast, PHS was caused only by frameshift/nonsense and splicing mutations. Second, among the frameshift/nonsense mutations, there was a clear genotype-phenotype correlation. Mutations in the first third of the gene (from open reading frame [ORF] nucleotides [nt] 1-1997) caused GCPS, and mutations in the second third of the gene (from ORF nt 1998-3481) caused primarily PHS. Surprisingly, there were 12 mutations in patients with GCPS in the 3' third of the gene (after ORF nt 3481), and no patients with PHS had mutations in this region. These results demonstrate a robust correlation of genotype and phenotype for GLI3 mutations and strongly support the hypothesis that these two allelic disorders have distinct modes of pathogenesis.

Published
2005

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