Your search keyword '"W. Rens"' showing total 124 results

1. Cytogenetic Mapping of H1 Histone and Ribosomal RNA Genes in Hybrids between Catfish Species Pseudoplatystoma corruscans and Pseudoplatystoma reticulatum

Author

Malcolm A. Ferguson-Smith, W. Rens, Fernanda Dotti do Prado, Diogo Teruo Hashimoto, Fábio Porto-Foresti, and Fausto Foresti

Subjects

Genetics, Pseudoplatystoma reticulatum, biology, Physical Chromosome Mapping, Pseudoplatystoma corruscans, Ribosomal RNA, biology.organism_classification, Molecular biology, 18S ribosomal RNA, 5S ribosomal RNA, Histone H1, Gene cluster, Molecular Biology, Genetics (clinical)

Abstract

A physical chromosome mapping of the H1 histone and 5S and 18S ribosomal RNA (rRNA) genes was performed in interspecific hybrids of Pseudoplatystoma corruscans and P. reticulatum. The results showed that 5S rRNA clusters were located in the terminal region of 2 chromosomes. H1 histone and 18S ribosomal genes were co-localized in the terminal portion of 2 chromosomes (distinct from the chromosomes bearing 5S clusters). These results represent the first report of association between H1 histone and 18S genes in fish genomes. The chromosome clustering of ribosomal and histone genes was already reported for different organisms and suggests a possible selective pressure for the maintenance of this association.

Published

2012

2. Chromosome Mapping of H1 Histone and 5S rRNA Gene Clusters in Three Species of Astyanax (Teleostei, Characiformes)

Author

Malcolm A. Ferguson-Smith, Fausto Foresti, Fábio Porto-Foresti, Diogo Teruo Hashimoto, and W. Rens

Subjects

Genetics, Teleostei, Chromosome, Biology, Characiformes, biology.organism_classification, body regions, 5S ribosomal RNA, Histone H1, Neotropical fish, Molecular Biology, Ribosomal DNA, Gene, Genetics (clinical)

Abstract

We report here on the physical mapping of the H1 histone genes (hisDNA) and the 5S ribosomal DNA (rDNA) in 3 Neotropical fish species of the genus Astyanax(A. altiparanae, A. bockmanni and A. fasciatus) and the comparative analysis of the chromosomes bearing these genes. Nucleotide analyses by sequencing of both genes were also performed. The distribution of the H1 histone genes was more conserved than that of the rRNA genes, since these were always located in the pericentromeric regions of 2 chromosome pairs. 5S rDNA was found on one of the pairs that presented an H1 histone cluster; this seems to be a conserved chromosomal feature of the genus Astyanax. In addition, individuals of A. bockmanni and A. fasciatus showed clusters of 5S rDNA on 1 pair of acrocentric chromosomes, not found in A. altiparanae. The results obtained by chromosome mapping as well as by sequencing of both genes showed that A.bockmanni is more closely related to A. fasciatus than to A. altiparanae. The results allow the characterization of cytogenetic markers for improved elucidation of the processes involved in karyotype differentiation of fish genomes.

Published

2011

3. The unique sex chromosome system in platypus and echidna

Author

M. A. Ferguson-Smith and W. Rens

Subjects

Genetics, Autosome, biology, Karyotype, Y chromosome, biology.organism_classification, biology.animal, parasitic diseases, Echidna, Small supernumerary marker chromosome, Platypus, Sex linkage, X chromosome

Abstract

A striking example of the power of chromosome painting has been the resolution of the male platypus karyotype and the pairing relationships of the chain of ten sex chromosomes. We have extended our analysis to the nine sex chromosomes of the male echidna. Cross-species painting with platypus shows that the first five chromosomes in the chain are identical in both, but the order of the remainder are different and, in each species, a different autosome replaces one of the five X chromosomes. As the therian X is homologous mainly to platypus autosome 6 and echidna 16, and as SRY is absent in both, the sex determination mechanism in monotremes is currently unknown. Several of the X and Y chromosomes contain genes orthologous to those in the avian Z but the significance of this is also unknown. It seems likely that a novel testis determinant is carried by a Y chromosome common to platypus and echidna. We have searched for candidates for this determinant among the many genes known to be involved in vertebrate sex differentiation. So far fourteen such genes have been mapped, eleven are autosomal in platypus, two map to the differential regions of X chromosomes, and one maps to a pairing segment and is likewise excluded. Search for the platypus testis-determining gene continues, and the extension of comparative mapping between platypus and birds and reptiles may shed light on the ancestral origin of monotreme sex chromosomes.

Published

2010

4. Contents Vol. 127, 2009

Author

B.G. Hanks, D. Rose, I. Arikura, J.W. Sites, L. Kupriyanova, Chris Moran, P. Nisi Cerioni, M. Giovannotti, R. Iiizumi, V.P. Orunganti, T. Ezaz, H.R. Patel, Ettore Olmo, K. Majumdar, Louis J. Guillette, M.T. Rodrigues, S. Mangalipalli, L. Singh, M. Nakano, S.R. Priya, Y. Takahashi, S. Kubota, S. Kitakawa, D. Tosh, Taisen Iguchi, S.D. Sarre, C. Moritz, W. Gu, M.A. Ferguson-Smith, W. Rens, A. Tiwari, P.C.M. O’Brien, Sally R. Isberg, W.P. Hall, M.M. Laguna, V. Trifonov, N. Valenzuela, Y. Shibaike, R.C. Amaro, K.C.M. Pellegrino, E. Olmo, A. Anand, K. Ohne, H. Ota, D. O’Meally, C.L. Parkinson, F.L. Lovell, A. P. J. de Koning, C. King, R.M.L. dos Santos, Todd A. Castoe, Z.J. Jiang, M. Watanabe, Adam D. Leaché, R.K. Aggarwal, Y. Katsu, Lee G. Miles, D. Kordis, V. Caputo, H. Ferrarezzi, N. Oguiura, R. Turlapati, Chris L. Organ, P. Dalzell, Scott V. Edwards, V. Murtagh, M Sakai, J.W. Bickham, M. Patel, Y. Yonenaga-Yassuda, A. Georges, E.L. Braun, N. Akakubo, B. Panda, Travis C. Glenn, H. Tanaka, Daniel E. Janes, C. Imaoka, H. Shiro, H. Miller, M.K. Kulashekaran, David D. Pollock, Satomi Kohno, R.K. Mishra, J.M. Daza, L. Rao, R.F. Batistic, J.A. Marshall Graves, and M.K. Fujita

Subjects

Botany, Genetics, Zoology, Biology, Molecular Biology, Genetics (clinical)

Published

2009

5. Contents Vol. 121, 2008

Author

I. Babić, K. Kumke, P. Sirleto, M. Guerra, E. Gebhart, X. Liang, F. Pelliccia, A. Curatolo, L.-Y. Li, G. Queipo, C. Kopp, I. Palma, C. Soderberg, A.G. O’Reilly, K. Nieto, M. Kapović, M. Volleth, S.B. Olson, P.A. Wheeler, C.M. Ramsdell, E. Capanna, M.D. López-León, T. Sato, G. Emmert, N. Bosco, R.J. O’Neill, P. Grzmil, R. de la Herrán, N. Ohkohchi, P.C.M. O’Brien, E. Matoso, J.I. Navas, M. Switonski, R.E. Moses, Y.R. Peña, T.E. Mirkov, T.V. Karamysheva, L. Chavez, T. Matsumoto, A. Rocchi, A.G. Bugrov, H. Mizuno, I.M. Carreira, H. Tönnies, J. Hejna, J. Olvera, D.S. Perez, S. Kofman-Alfaro, C. Ruiz Rejón, M.C. Digilio, I.Y. Iourov, E. Aygören-Pürsün, R.N. Jones, R.B. Phillips, Y.B. Yurov, W. Rens, N.B. Rubtsov, A. Hemphill, R. Castiglia, A. Lombardo, J. Nowacka-Woszuk, H. Kiyosawa, C.J. Obergfell, T. Sasaki, J. Rubes, M.J. Julião, G.H. Thorgaard, I. López-Flores, M. Andersson, K. Bork, I. Szczerbal, A.C. Tomaiuolo, B. Brajenović-Milić, T. Rzymski, M. Kubo, M.J. O’Neill, K. Mrasek, K.-L. Sun, C.R. Müller, J. Saraiva, Y.M.N. Akkari, Z. Modrušan-Mozetić, J. Vraneković, J. Li-Ling, V.V. Monakhov, G. Krüger, I. Martinez-Saguer, H. Yasue, Z.-G. Li, A. Kocot, M.A. Alfaqih, J. Cabrero, J. Müller-Navia, O.C. Ukpo, E.J. Moore, M.J. Dewey, W. Kreuz, N. Nájera, A. Meinhardt, I.V. Soloviev, E. Rusicke, M. Ruiz Rejón, T. Liehr, A. Weise, A.P. Moraes, J.P.M. Camacho, W.-N. Fu, M. Herrera, I. Bauer, A. Mascarenhas, L.-L. Wang, V.V. Dzyubenko, M.A. Garrido-Ramos, A.E. Hanlon Newell, S. Wolf, D. Kademani, E. Gornung, H. Cernohorska, T. Göβwein, A. Gerlach, A.H. Rezaeian, J.B. Melo, J. Oldenburg, F. Robles, T. Miura, E.E. Mlynarski, A. Houben, R. Capolino, D. Aguirre, P. Burfeind, D.I. Smith, A. Angioni, M.C. Roberti, M. Chiba, I. Hachero, C. Surace, J. Sosnowski, and S.G. Vorsanova

Subjects

Botany, Genetics, Zoology, Biology, Molecular Biology, Genetics (clinical)

Published

2008

6. Ellobius lutescens: Sex Determination and Sex Chromosome

Author

Annette Baumstark, W. Rens, W. Vogel, Irina Bakloushinskaya, Horst Hameister, N. Schäfer, Alexander S. Graphodatsky, A. Süss, and Walter Just

Subjects

Genetics, Embryology, Autosome, biology, Endocrinology, Diabetes and Metabolism, Chromosome, social sciences, biology.organism_classification, X-inactivation, Ellobius, Testis determining factor, parasitic diseases, Vole, geographic locations, X chromosome, Sex linkage, Developmental Biology

Abstract

The mole vole Ellobius lutescens is an interesting animal, not only concerning its sex determination mechanism without the Y-chromosomal Sry gene, that triggers sex determination in nearly all other mammalian species, but also regarding the karyotype with an odd number of chromosomes, being identical in male and female animals. The odd chromosome represents the X chromosome, and therefore, even males do not have a Y chromosome. We present an overview of a search for candidate genes of male sex determination in the mole vole Ellobius lutescens. A singular X raises questions about the need for X chromosome inactivation in female cells. We present preliminary data that support a hypothesis that the E. lutescensXist gene may be degenerated and thus non-functional.

Published

2007

7. A ZZ/ZW sex chromosome system in the thick-tailed Gecko ( Underwoodisaurus milii; Squamata: Gekkota: Carphodactylidae), a member of the ancient gecko lineage

Author

M, Pokorná, W, Rens, M, Rovatsos, and L, Kratochvíl

Subjects

Evolution, Molecular, Male, Sex Chromosomes, Animals, Female, Lizards, Sex Determination Processes, Phylogeny, Chromosome Banding

Abstract

Geckos (Gekkota) are a highly diversified group of lizards with an exceptional diversity in sex-determining systems. Despite this intriguing documented variability, data on sex determination in many lineages is still scarce. Here, we document the previously overlooked heteromorphic ZZ/ZW sex chromosomes in the thick-tailed gecko, Underwoodisaurus milii, a member of the ancient lineage of pygopodoid geckos. The finding of female heterogamety within pygopodoid geckos was unexpected, as until now only male heterogamety and environmental sex determination have been reported in this group, and female heterogamety was known only in distantly related gecko families separated from the pygopodoid geckos around 150 million years ago. The W chromosome in U. milii is highly heterochromatic and contains a large number of telomeric-like repeats comparable to around 50% of all telomeric-like sequences present in male genomes. The accumulation of these repeats might have been responsible for the considerable size expansion of the W chromosome in comparison to the Z chromosome. The heteromorphic ZZ/ZW sex chromosomes with accumulated telomeric-like repeats in the thick-tailed geckos further illustrate the exceptional diversity of sex-determining systems in geckos and add important information to our understanding of the evolution and phylogeny of sex-determining systems in reptiles.

Published

2013

8. Contents Vol. 102, 2003

Author

H.A. Lewin, G. Pielberg, H.B. Park, V. Russo, R.W. Dunstan, M. Niikura, A. Fu, H. Hayes, C. Moran, J. Womack, S. Kubickova, M.A. Ferguson-Smith, J.L. Williams, J.L. Myka, J. van der Poel, Loren C. Skow, B. van Hest, M. Menotti-Raymond, David L. Adelson, J. Schläpfer, H. Bird, J.R. Garbe, A.A. Schäffer, N. Yasinetskaya, M. Marra, K. Jacobs, C. Elduque, Y. Da, F. Yang, E.G. Cothran, W.J. Murphy, D. Zudova, P. Chardon, V. Amarger, E.P. Cribiu, Y. Zhang, D. Gallagher, R. Rullo, L.B. Madsen, M. Zanotti, L. Krejci, L. Molteni, M. Van Poucke, L. Harman, J.W. Keele, M.M. Binns, C. Genêt, J.N. Derr, J. Schein, B. Backofen, S. Peto, G. Guérin, Donald Miller, F.A. Ponce de León, R. Voß-Nemitz, S. Kiuchi, J.A.M. Graves, S. Cirera, Thomas Faraut, C. Garcia, P.J. de Jong, A.L. Gustafson, O.A. Ryder, W.-S. Liu, R. Stephens, J. Rubes, A. Crisà, S. Braglia, T.L. Lear, C.B. Jørgensen, M.V. Arruga, M.F. Rothschild, H. Uenishi, N.P. Carter, O. Ryder, J.A. Price, N. Iannuccelli, Samodha C. Fernando, C. Baiocco, M. Dunø, K. Benke, L.M. Daniels, J.R. Mickelson, A. Valentini, K.M. Reed, K.E. Murphy, B. Benkel, O.R.P. Bininda-Emonds, G. Brown, H.H. Cheng, D. Milenkovic, B. Koop, B. Brenig, Doris M. Kupfer, S. So, L. Iannuzzi, V. Fillon, Y. Chen, A.T.V. Pillai, M.L. Cox, C.W. Beattie, M.L. Houck, N.E. Raney, C. Drögemüller, N. Bosak, Jillian F. Maddox, L. Fontanesi, T.L. Ward, L.D. Chaves, B.P. Chowdhary, L. Alexander, H.-C. Liu, R. Erlandsson, L. Nanni Costa, C.A. Gill, M. Mattheeuws, T. Bønsdorff, N. Rogalska-Niznik, R. Agarwala, M. Schmid, B. Lama, K.A. Greer, A. Van Zeveren, Y. Meng, G. Rohrer, M. Yerle, J.E. Fulton, M. Breen, L.J. Peelman, C. Li, H. Yasue, B. Fu, H.P. Klinger, R.P.M.A. Crooijmans, V. Cantegrel, E. Bailey, T. Veenendaal, S. Mikawa, V.D. Rilington, S. Marklund, M.C. Savarese, S. Mashima, B.J. Ostroski, I. Szczerbal, H. Fiegler, A.H. Petersen, A. Vignal, D.E. Harry, K. Osoegawa, J. Klukowska, H. Hiraiwa, L. Chemnick, L. Schibler, J. Aldenhoven, A. Jaadar, B.W. Kirkpatrick, C. Hansen, V.A. David, M. Longeri, S.I. Anderson, F. Kasai, E. Scotti, S.S. Moore, G. Bongioni, D. Incarnato, S.J. Valberg, A. Eggen, I.R. Franklin, T. Zharkikh, J. Quackenbush, L.D. Lieto, M. Gautier, C. Marchitelli, Bruce A. Roe, E. Cribiu, K.M. Credille, E.J. Cargill, R. Middleton, M .A.M. Groenen, Y. Palti, O. Rezacova, N. Ramlachan, W. Zimmermann, R. Fries, Terje Raudsepp, J.-T. Jeon, C.W. Ernst, E.A. Ostrander, F. Martins-Wess, Udaya DeSilva, L. Andersson, C.E. Rexroad, A. Winter, C.M. Seabury, Y. Lee, M.N. Romanov, V.H. Nielsen, W. Rens, R.D. Schnabel, M.E. Delany, K. Hemmatian, R. Guyon, S.E. Swanberg, M. van Eckeveld, C. Schelling, B.S.D. Urquhart, A. Galli, P.J. Venta, J.F. Taylor, S. Cornelissen, J.B. Dodgson, K.L. Tsai, K. Sandberg, L. Ferretti, G.P. Di Meo, Rebecca L. Tallmadge, Bhanu P. Chowdhary, W. Bridge, C.R. Farber, C. Penado, Alan Archibald, D. Milan, R. Davoli, T.J. Robinson, H. Fairclough, P.C.M. O’Brien, M. Switonski, F. Galibert, T. Leeb, S.J. O’Brien, T. Hayashi, F.A. Habermann, A. Perucatti, Fares Z. Najar, T. Lear, C. Bendixen, Douglas F. Antczak, B. Thomsen, L. Buttazzoni, J. Aerts, J.E. Swinburne, R. Thomas, X. Guo, S.A. Gahr, M. Fredholm, P.H. Nissen, A. Robic, I. Edfors-Lilja, S. Karamycheva, G. Dolf, L.A. Clark, Y. Lahbib-Mansais, L. Skow, Noelle E. Cockett, G.Q. Fitch, and A.T. Bowling

Subjects

Botany, Genetics, Biology, Molecular Biology, Genetics (clinical)

Published

2003

9. Subject Index Vol. 102, 2003

Author

P.H. Nissen, I. Edfors-Lilja, J. Aerts, R. Thomas, X. Guo, M.A. Ferguson-Smith, L. Molteni, M. Fredholm, B. Koop, P.J. Venta, H. Bird, J.N. Derr, T. Zharkikh, J. Quackenbush, M. Marra, R.W. Dunstan, H.A. Lewin, G. Pielberg, L. Chemnick, L.A. Clark, Y. Lahbib-Mansais, N. Ramlachan, Noelle E. Cockett, A. Fu, H. Hayes, G.Q. Fitch, H. Fiegler, A.T. Bowling, E.P. Cribiu, D. Gallagher, R. Rullo, B. Backofen, J.-T. Jeon, C.W. Ernst, H.P. Klinger, R.P.M.A. Crooijmans, H. Yasue, J.L. Williams, V.D. Rilington, B. Fu, G. Rohrer, H.B. Park, V.A. David, F. Kasai, D.E. Harry, M. Zanotti, V. Amarger, R. Fries, Terje Raudsepp, V. Russo, D. Incarnato, Loren C. Skow, I.R. Franklin, C. Marchitelli, S. Cirera, S.S. Moore, M.C. Savarese, K. Sandberg, S. Kubickova, J.F. Taylor, S. Cornelissen, L. Krejci, B.J. Ostroski, A.A. Schäffer, Thomas Faraut, K. Osoegawa, J. Klukowska, M. Gautier, C. Elduque, S. Mikawa, S. Marklund, Samodha C. Fernando, G. Guérin, Donald Miller, F.A. Ponce de León, A. Jaadar, F. Martins-Wess, C.E. Rexroad, Udaya DeSilva, L. Ferretti, K.L. Tsai, L.B. Madsen, E. Bailey, J. Schläpfer, E.A. Ostrander, G.P. Di Meo, J. van der Poel, Bruce A. Roe, J.L. Myka, E. Scotti, H.H. Cheng, E.G. Cothran, G. Bongioni, L. Andersson, A. Winter, M.E. Delany, W.J. Murphy, D. Zudova, T.L. Ward, C. Baiocco, A. Crisà, Rebecca L. Tallmadge, W. Rens, J. Aldenhoven, Bhanu P. Chowdhary, K.E. Murphy, M.F. Rothschild, R.D. Schnabel, M.L. Cox, J.R. Mickelson, A. Valentini, M. Niikura, V. Fillon, M.V. Arruga, C.M. Seabury, M. van Eckeveld, C. Schelling, C. Genêt, J.W. Keele, B.W. Kirkpatrick, M. Schmid, E. Cribiu, C.R. Farber, C. Li, N. Rogalska-Niznik, Y. Chen, J.A. Price, C. Drögemüller, O.R.P. Bininda-Emonds, L.D. Chaves, M.L. Houck, N.E. Raney, C. Penado, K.M. Credille, Alan Archibald, B. Lama, S.J. Valberg, O. Rezacova, B.S.D. Urquhart, A. Eggen, M. Van Poucke, J.A.M. Graves, L. Iannuzzi, K. Benke, L.M. Daniels, B.P. Chowdhary, G. Brown, M. Yerle, Y. Da, F. Yang, S. Braglia, B. Brenig, M .A.M. Groenen, D. Milenkovic, I. Szczerbal, M. Mattheeuws, A.H. Petersen, Jillian F. Maddox, B. van Hest, W. Zimmermann, J.R. Garbe, R. Stephens, J. Rubes, Y. Lee, J. Schein, L. Alexander, H.-C. Liu, M.N. Romanov, M.M. Binns, M. Dunø, P.J. de Jong, A.L. Gustafson, S. Kiuchi, S.E. Swanberg, Y. Palti, B. Benkel, A. Van Zeveren, Y. Meng, C.B. Jørgensen, A. Galli, K.M. Reed, H. Uenishi, N.P. Carter, V.H. Nielsen, J.B. Dodgson, A.T.V. Pillai, C.W. Beattie, K. Hemmatian, R. Guyon, J.E. Fulton, N. Bosak, R. Erlandsson, A. Vignal, C. Moran, J. Womack, K. Jacobs, O. Ryder, Doris M. Kupfer, S. So, David L. Adelson, Y. Zhang, L. Harman, R. Voß-Nemitz, C. Garcia, K.A. Greer, L.J. Peelman, V. Cantegrel, T. Veenendaal, M. Longeri, S.I. Anderson, A. Robic, S. Karamycheva, R. Middleton, B. Thomsen, N. Iannuccelli, L. Buttazzoni, J.E. Swinburne, L. Fontanesi, L. Nanni Costa, C.A. Gill, H. Hiraiwa, S.A. Gahr, G. Dolf, S. Peto, L. Skow, T.L. Lear, L.D. Lieto, M. Breen, E.J. Cargill, T. Bønsdorff, R. Agarwala, M. Menotti-Raymond, N. Yasinetskaya, P. Chardon, W.-S. Liu, O.A. Ryder, S. Mashima, L. Schibler, C. Hansen, Douglas F. Antczak, S.J. O’Brien, T. Hayashi, F.A. Habermann, A. Perucatti, Fares Z. Najar, T. Lear, C. Bendixen, W. Bridge, D. Milan, R. Davoli, T.J. Robinson, H. Fairclough, P.C.M. O’Brien, M. Switonski, F. Galibert, and T. Leeb

Subjects

Index (economics), Statistics, Genetics, Subject (documents), Biology, Molecular Biology, Genetics (clinical)

Published

2003

10. Cytogenetic mapping of H1 histone and ribosomal RNA genes in hybrids between catfish species Pseudoplatystoma corruscans and Pseudoplatystoma reticulatum

Author

D T, Hashimoto, M A, Ferguson-Smith, W, Rens, F D, Prado, F, Foresti, and F, Porto-Foresti

Subjects

Fish Proteins, RNA, Ribosomal, 5S, Chromosome Mapping, Genes, rRNA, Polymerase Chain Reaction, Chromosomes, Histones, RNA, Ribosomal, Multigene Family, RNA, Ribosomal, 18S, Animals, Hybridization, Genetic, Catfishes, In Situ Hybridization, Fluorescence, Polymorphism, Restriction Fragment Length

Abstract

A physical chromosome mapping of the H1 histone and 5S and 18S ribosomal RNA (rRNA) genes was performed in interspecific hybrids of Pseudoplatystoma corruscans and P. reticulatum. The results showed that 5S rRNA clusters were located in the terminal region of 2 chromosomes. H1 histone and 18S ribosomal genes were co-localized in the terminal portion of 2 chromosomes (distinct from the chromosomes bearing 5S clusters). These results represent the first report of association between H1 histone and 18S genes in fish genomes. The chromosome clustering of ribosomal and histone genes was already reported for different organisms and suggests a possible selective pressure for the maintenance of this association.

Published

2012

11. Construction of Mouse Chromosome-specific DNA Libraries and Their Use for the Detection of X-ray-induced Aberrations

Author

P. De Boer, Adayabalam S. Balajee, Jacob A. Aten, Leon H.F. Mullenders, W. Rens, Adayapalam T. Natarajan, J. J. W. A. Boei, and Other departments

Subjects

Molecular Sequence Data, Pilot Projects, Chromosomal translocation, Biology, Polymerase Chain Reaction, Translocation, Genetic, Mice, chemistry.chemical_compound, Centromere, medicine, Animals, Radiology, Nuclear Medicine and imaging, Genomic library, Metaphase, In Situ Hybridization, Chromosome Aberrations, Genomic Library, Base Sequence, Radiological and Ultrasound Technology, medicine.diagnostic_test, Chromosome, DNA, Molecular biology, chemistry, Karyotyping, Female, DNA Probes, Molecular probe, Spleen, Whole-Body Irradiation, Fluorescence in situ hybridization

Abstract

We describe here the development of mouse chromosome-specific DNA libraries and their use in the detection of radiation-induced chromosome aberrations by fluorescence in situ hybridization. Large metacentric chromosomes, resulting from a translocation involving chromosomes 1, 11 and 13, were flow-sorted. Using a slit-scan technique for morphometric analysis, metacentric chromosomes were separated from normal acrocentric chromosomes and their aggregates. DNA from the metacentric chromosomes was amplified by PCR using the linker/adaptor method. In this pilot study, mouse was whole-body irradiated with 1, 2 and 3 Gy and aberrations were scored in metaphase spreads of splenocytes cultured in vitro. The results indicate that directly after radiation exposure, stable and unstable aberrations are induced at about equal frequencies in the splenocytes. The availability of chromosome-specific probes for mouse may prove very useful when analysing the behaviour of stable aberrations, as well as the testing of many suspected mutagenic carcinogens and aneugens in vivo for induction of chromosomal translocations and non-disjunction, respectively.

Published

1994

12. The unique sex chromosome system in platypus and echidna

Author

M A, Ferguson-Smith and W, Rens

Subjects

Male, X Chromosome, Species Specificity, Tachyglossidae, Y Chromosome, Animals, Female, Platypus, Chromosomes, Mammalian, Chromosome Painting

Abstract

A striking example of the power of chromosome painting has been the resolution of the male platypus karyotype and the pairing relationships of the chain often sex chromosomes. We have extended our analysis to the nine sex chromosomes of the male echidna. Cross-species painting with platypus shows that the first five chromosomes in the chain are identical in both, but the order of the remainder are different and, in each species, a different autosome replaces one of the five X chromosomes. As the therian X is homologous mainly to platypus autosome 6 and echidna 16, and as SRY is absent in both, the sex determination mechanism in monotremes is currently unknown. Several of the X and Y chromosomes contain genes orthologous to those in the avian Z but the significance of this is also unknown. It seems likely that a novel testis determinant is carried by a Y chromosome common to platypus and echidna. We have searched for candidates for this determinant among the many genes known to be involved in vertebrate sex differentiation. So far fourteen such genes have been mapped, eleven are autosomal in platypus, two map to the differential regions of X chromosomes, and one maps to a pairing segment and is likewise excluded. Search for the platypus testis-determining gene continues, and the extension of comparative mapping between platypus and birds and reptiles may shed light on the ancestral origin of monotreme sex chromosomes.

Published

2011

13. Chromosome mapping of H1 histone and 5S rRNA gene clusters in three species of Astyanax (Teleostei, Characiformes)

Author

D T, Hashimoto, M A, Ferguson-Smith, W, Rens, F, Foresti, and F, Porto-Foresti

Subjects

Histones, Multigene Family, Fishes, RNA, Ribosomal, 5S, Animals, Chromosome Mapping

Abstract

We report here on the physical mapping of the H1 histone genes (hisDNA) and the 5S ribosomal DNA (rDNA) in 3 Neotropical fish species of the genus Astyanax(A. altiparanae, A. bockmanni and A. fasciatus) and the comparative analysis of the chromosomes bearing these genes. Nucleotide analyses by sequencing of both genes were also performed. The distribution of the H1 histone genes was more conserved than that of the rRNA genes, since these were always located in the pericentromeric regions of 2 chromosome pairs. 5S rDNA was found on one of the pairs that presented an H1 histone cluster; this seems to be a conserved chromosomal feature of the genus Astyanax. In addition, individuals of A. bockmanni and A. fasciatus showed clusters of 5S rDNA on 1 pair of acrocentric chromosomes, not found in A. altiparanae. The results obtained by chromosome mapping as well as by sequencing of both genes showed that A.bockmanni is more closely related to A. fasciatus than to A. altiparanae. The results allow the characterization of cytogenetic markers for improved elucidation of the processes involved in karyotype differentiation of fish genomes.

Published

2010

14. Detection of recurrent chromosome abnormalities in Ewing's sarcoma and peripheral neuroectodermal tumor cells using bivariate flow karyotyping

Author

Rogier Versteeg, Rosalyn Slater, Erik M. M. Manders, W. Rens, G A Boschman, Jacob A. Aten, and Other departments

Subjects

Cancer Research, Pathology, medicine.medical_specialty, Chromosomes, Human, Pair 22, Bone Neoplasms, Chromosomal translocation, Sarcoma, Ewing, Biology, Translocation, Genetic, Flow cytometry, chemistry.chemical_compound, Tumor Cells, Cultured, Genetics, medicine, Humans, Neuroectodermal Tumors, Primitive, Peripheral, Metaphase, Chromosome Aberrations, medicine.diagnostic_test, Chromosomes, Human, Pair 11, Chromosome, Ewing's sarcoma, Chromomycin A3, Karyotype, DNA, Neoplasm, Neoplasms, Germ Cell and Embryonal, Flow Cytometry, medicine.disease, chemistry, Cell culture, Karyotyping, Immunology, Bisbenzimidazole

Abstract

Bivariate flow karyotyping can be used for the detection of recurrent chromosome abnormalities in tumor cells. For this purpose 2 cell lines originally derived from Ewing's sarcomas and 4 cell lines from peripheral neuroectodermal tumors were used. The characteristic t(11;22) was known to be present in 5 cell lines. The remaining cell line was known to have a variant t(2;11;22;21) translocation. Metaphase chromosomes were stained with the fluorescent dyes Hoechst 33258 and Chromomycin A3 and analyzed subsequently using bivariate flow cytometry. The resulting bivariate flow karyotypes of the tumor cells were normalized by a standardized procedure using a computerized method and compared with a reference flow karyotype of normal chromosomes. In 5 cell lines two recurring abnormal chromosome peaks were identified at positions expected for the der(11) and der(22) chromosomes characteristic for the reciprocal t(11;22)(q24;q12). In the remaining cell line with the variant t(2;11;22;21), only the peak representing the der(22) was identifiable. It is concluded that bivariate flow karyotyping can be used for the semiautomated detection of recurrent translocations and the assessment of their variability among different tumors. © 1992 Wiley-Liss, Inc.

Published

1992

15. Contents Vol. 92, 2001

Author

L. Iannuzzi, C. Broccardo, Y. Mao, J.J.M. van Groningen, W.D. Phillips, J. Wang, J. Rathjen, T. Krieg, D.S. Gallagher, F. Sangiuolo, P. Lichter, M. Wilbrink, P.D. Rathjen, N.W. Richards, K.-M. Debatin, Y. Matsuda, A. Vaiman, K.J. Portbury, P. Perelman, F. Bourgeois, X. Huang, D.L. Gumucio, I. Jentsch, S.S. Bhattacharya, Q. Jiang, K. Ying, I. Matera, A. Rösen-Wolff, C. Mas, K. Ogura, J. Koch, S. Kiuru-Kuhlefelt, C. Auffray, P. Denèfle, R. Allikmets, M. Miettinen, S. Schmutz, M.P. Hildebrand, I. Arnould, C. Prades, R. Sauer, C. Sapienza, R.B. Voyle, F. Yang, M. Gahr, L.J. Coignet, A. Kuroiwa, C.G. Scheuerpflug, N. Serdukova, W.O. Bauer, L.M. Gulluyan, B. Brewer, M. Simonneau, J. Fanburg-Smith, A.S. Graphodatsky, I. Kola, C. Stover, M. Sancandi, J. Dai, W. El-Rifai, Y. Obara, M. Bozzali, M.-D. Devignes, E. Reichenberger, A.G. Marneros, T. Otoguro, B.R. Olsen, A. Botta, C. Drögemüller, A. Mincheva, W. Schwaeble, W. Wang, F. Jakob, S-I. Kawada, L. Naudin, B. Jordan, T. Isobe, M.R. Speicher, G. Palumbo, L. Granjon, S. Knuutila, C. Chelala, A. Bulfone, K. Engel, A. Hoffmann, E. Kater-Baats, H. Kuiper, R. Ravazzolo, G. Gradl, S. Fojo, Z. Zhou, M. Schmid, N. Serakıncı, D. Di Berardino, J. Rubes, I. Ceccherini, K. Matsumoto, B. Dallapiccola, K. Tsuchiya, J.M. Moalic, M.A. Lee-Kirsch, S. Galiègue-Zouitina, G. Merkx, S. Thomas, M.A.J. Weterman, V.T. Volobouev, M. Dean, M. Stumm, G. Novelli, F. Guimiot, N. Tommerup, M. Fredholm, A. Baldini, V. Jurecic, N.B. Atkin, W. Zhao, C. Hansen, W. Nie, G.P. Di Meo, I. Gustavsson, M. van Rooijen, S. Cirera, A.T. Remaley, J. Osorio, S. Imbeaud, R. Cinti, F. Amati, R.-D. Wegner, E. Conti, S. Murray, A. Geurts van Kessel, A. Pizzuti, C.M. Owczarek, K. Friis Henriksen, S. Halford, C. Lafargue, R. Tang, C.Y. Gregory-Evans, S. Cui, C.P. Popescu, P.J. Hertzog, T. Leeb, T. Ogura, P.E. Schaner, M. Kuro-o, Diederik R.H. de Bruijn, S. Shulenin, P. Wieacker, W. Rens, N.A. Jenkins, B. Pedersen, M. Fava, H.R. Treutlein, C. Roumier, M. Berloco, F. Pardo-Manuel de Villena, M. Rosier, P.C.M. O’Brien, N.D. Ebenezer, L. Kutschke, D. Fukushi, E.P. Cribiu, A. Ratti, G. Beck, O. Distl, M.-F. Luciani, S.E. Antonarakis, M. Eleveld, Y. Huang, R.M. Hope, J. Kere, J.A. Kennell, Y. Xie, B.S. Milne, M.A. Ferguson-Smith, S. Neubauer, J. Womack, R. Zoorob, H. Hayes, A. Eggen, N.G. Copeland, B. Levacher, Y.-A. Lee, B. Sicard, M. Bak, S.X. Liang, D.J. Gilbert, G. Stranzinger, E. Paditz, H. Mehenni, R. Wieser, G. Chimini, M.G. Mattei, L.M. Schriml, S. Keindorff, I. Nanda, and M. Shichiri

Subjects

Botany, Genetics, Biology, Molecular Biology, Genetics (clinical)

Published

2000

16. Peromyscus maniculatus--Mus musculus chromosome homology map derived from reciprocal cross species chromosome painting

Author

E E, Mlynarski, C J, Obergfell, W, Rens, P C M, O'Brien, C M, Ramsdell, M J, Dewey, M J, O'Neill, and R J, O'Neill

Subjects

Mice, Peromyscus, Species Specificity, Animals, Chromosome Mapping, Cells, Cultured, Chromosome Painting

Abstract

The Mus musculus and Rattus norvegicus genomes have been extensively studied, yet despite the emergence of Peromyscus maniculatus as an NIH model for genome sequencing and biomedical research much remains unknown about the genome organization of Peromyscines. Contrary to their phylogenetic relationship, the genomes of Rattus and Peromyscus appear more similar at the gross karyotypic level than either does to Mus. We set out to define the chromosome homologies between Peromyscus, Mus and Rattus. Reciprocal cross-species chromosome painting and G-band homology assignments were used to delineate the conserved chromosome homology map between P. maniculatus and M. musculus. These data show that each species has undergone extensive chromosome rearrangements since they last shared a common ancestor 25 million years ago (mya). This analysis coupled with an inferred homology map with Rattus revealed a high level of chromosome conservation between Rattus and Peromyscus and indicated that the chromosomes of Mus are highly derived.

Published

2008

17. On-line sorting of human chromosomes by centromeric index, and identification of sorted populations by GTG-banding and fluorescent in situ hybridization

Author

G A Boschman, W. Rens, G. W. Barendsen, Erik M. M. Manders, C van Oven, Jacob A. Aten, and Other departments

Subjects

medicine.medical_specialty, G banding, Centromere, Biology, Online Systems, Giemsa stain, Cell Line, Genetics, medicine, Chromosomes, Human, Humans, Metaphase, Genetics (clinical), Fluorescent Dyes, Chromosome 13, Hybridization probe, Cytogenetics, Nucleic Acid Hybridization, Chromosome, Karyotype, DNA, Fibroblasts, Flow Cytometry, Molecular biology, Chromosome Banding, Karyotyping, DNA Probes

Abstract

Using slit-scan flow cytometry, the shape of human metaphase chromosomes, as expressed in their centromeric index (CI), and the DNA content of the chromosomes have been used as parameters in bivariate flow karyotyping. The resolution of the DNA vs CI flow karyogram of the larger chromosomes up to chromosome 13 is much higher than the resolution obtained in the DNA-based monovariate flow karyogram. Chromosome length appears to be an important factor in the resolution of the DNA vs CI-based flow karyogram. A method has been developed to obtain chromosomes in suspension that are long enough for adequate analysis. Several chromosomes that cannot be distinguished or are difficult to discriminate in the DNA-based karyogram can now be distinguished as individual peaks, e.g., chromosomes 1 and 2. The peak of chromosomes 9-12 can be separated into two peaks formed by chromosomes 9 and 11, and 10 and 12, respectively. The advantage of the system applied in this study is that the DNA vs CI analysis is performed on-line, allowing chromosomes to be sorted on the bases of their CI. Pulse shapes of the selected chromosomes can be recorded simultaneously with the transmission of the sorting command. The purity of the sorted fraction can be estimated from the off-line inspection of these pulse shapes. Fractions of chromosome 1 have been sorted out on the basis of the CI information, centrifuged on slides, fixed and subsequently banded with trypsin and Giemsa or hybridized with the chromosome 1 specific probe, pUC 1.77. The observed purity under the selected conditions ranges from 80%-99% and is in accordance with the estimates of the purities made on the basis of the simultaneously recorded pulse shapes. Fixation of the chromosome suspension prior to flow cytometric analysis and sorting appears to be essential for the preservation of their morphology and has no adverse influence on the resolution of Giemsa banding or on the quality of in situ hybridization.

Published

1990

18. Contents Vol. 86, 1999

Author

D. Quincey, Y.-O. Kim, N. Sato, T. Leeb, L.J. Conner, A. Veronese, H. Satoh, C.G. Jakobsen, L. Martins, S.E. Hayes, E. Gentile, Manfred Gessler, F. Hosoda, M. Kinebuchi, C. Lemercier, O. Marcu, K. Hoehn, S.-Y. Park, T. Hardt, G. Barbanti-Brodano, F. Yang, Mariano Rocchi, Masanori Hatakeyama, T. Torii, T. Kitamura, N. Serakıncı, W. Mann, S. Osborne Lawrence, B. Brenig, D.G. Stathakis, H.-J. Koh, E. Verdin, Y. Franke, Masaki Okano, G. Pottier, K. Amimoto, Grant C. Sellar, N. Spieker, P.A. Martin-DeLeon, A. Strub, E. Li, M.-D. Devignes, X. Reveles, C. Roussakis, P. Grossfeld, N. Miyasaka, L.F.M. van Zutphen, S.A.N. Goldstein, M. Lepke, A. Tunnacliffe, G.N. Hendy, N.A. Manjunath, X. Deng, K. Georgas, U. Mahlknecht, K. Kikuchi, U. Sohn, A. Fogli, P.J. Yarowsky, P.C.M. O’Brien, W. Van Hul, T. Kozaki, L. Burridge, W. Wuyts, D. Masson, S. Forbes, J.P. Murnane, J. Stamberg, L. Viggiano, R. Favier, H. Kawakami, N. Katsanis, Matthew Breen, L.E. Stramm, L. Reid, P. Lustenberger, H.-H. Ropers, M. Athanasiou, S. Grimmond, K. Smith, M. Schmid, J.-Å. Gustafsson, D.S. Gerhard, J. Cruces, H. Narimatsu, J.L. Marsh, C-C. Hu, S. Katabami, Katsuzumi Okumura, L.A. Rethy, Y.-J. Kang, C.N. Sprung, B. Zabel, V. Bhide, P. Taschner, M. Trubia, S.-H. Kim, T. Haaf, Teijiro Aso, P.G. Gallagher, Marcel M.A.M. Mannens, T. Shiina, P.A. Ioannou, E. Schuuring, M.A. Ferguson-Smith, K. Yamada, R.J. Peoples, H. Inoko, D. Hoelzer, Y.-K. Wang, S. Stilgenbauer, R. Carrozzo, W. Rens, J. Harris, K. Yuri, E. Karayianni, A. De Paepe, T. Taguchi, H. Iwasaki, K. Krejčí, D. Carbonnelle, M. Hattori, L.A. Pérez Jurado, G. Gaudray, M.C. Yoshida, J. Justesen, G.F. Carle, I. Nanda, H.C. Au, M. Zollo, Veronica van Heyningen, J.T. Mascarello, R. Bucala, S.-H. Park, L.L. Hansen, S. Takai, Y. Shi, T. Kudo, M. Ohki, S. Raynaud, T. Watanabe, C. Turc-Carel, C.L. Pin, R. Korstanje, G. Chenevix-Trench, T. Miyachi, N. Van Roy, D.H. Spathas, C. Jacquot, M. Kaneko, C. Talbot, C. Magnanini, F.A. Ponce de León, Rogier Versteeg, Barbara R. DuPont, Glen A. Evans, R. Koike, R. Taramelli, H.-Z. Chen, N.A. Jenkins, C. Morelli, Shin-ichiro Takebayashi, Franki Speleman, P. Zisimopoulou, H. Hummerich, G.P. Holmes, A. Matsuura, H.A. van Lith, V. Orphanos, T. Kuramoto, P. Gaudray, T.K. Watanabe, T. Iizuka, D.J. Gilbert, S. Nakamura, F. Grummt, I.E. Scheffler, A.A. Bosma, M. Tixier-Boichard, C. Berger, C. Desmaze, H. Maruyama, Melissa H. Little, C. Alberti, F. Parente, G. Arrigo, K. De Boulle, N.G. Copeland, M. Selkirk, T. Mattina, M. Rosati, L. Sabatier, A. Calender, S.F. Konieczny, S. Sabbioni, Jet Bliek, M. James, M. Gordon, S. Giglio, Peter Little, T. Liehr, L. Canaff, N. Saitou, P.J. Willems, M.G. Denis, G.M. Maniatis, Nicoletta Archidiacono, L.V. Debelenko, O. Zuffardi, J.P. Simmer, J.J. Bitgood, K. Ladjali-Mohammedi, T. Thangarajah, B. Gawin, H. Himmelbauer, C. Lo Nigro, U. Francke, T.-L. Huh, M. Horie, C.M. Croce, J. Strovel, C. Staib, P. Bray-Ward, G. Weber, J. Koch, K. Kitada, Giovanna Grimaldi, J. Kalla, T. Serikawa, and M. Negrini

Subjects

Botany, Genetics, Biology, Molecular Biology, Genetics (clinical)

Published

1999

19. Ellobius lutescens: sex determination and sex chromosome

Author

W, Just, A, Baumstark, A, Süss, A, Graphodatsky, W, Rens, N, Schäfer, I, Bakloushinskaya, H, Hameister, and W, Vogel

Subjects

Male, Sex Chromosomes, Arvicolinae, Animals, Female, Genomics, Sex Determination Processes

Abstract

The mole vole Ellobius lutescens is an interesting animal, not only concerning its sex determination mechanism without the Y-chromosomal Sry gene, that triggers sex determination in nearly all other mammalian species, but also regarding the karyotype with an odd number of chromosomes, being identical in male and female animals. The odd chromosome represents the X chromosome, and therefore, even males do not have a Y chromosome. We present an overview of a search for candidate genes of male sex determination in the mole vole Ellobius lutescens. A singular X raises questions about the need for X chromosome inactivation in female cells. We present preliminary data that support a hypothesis that the E. lutescens Xist gene may be degenerated and thus non-functional.

Published

2007

20. Single UV excitation of Hoechst 33342 and propidium iodide for viability assessment of rhesus monkey spermatozoa using flow cytometry

Author

K Cai, W Rens, Weizhi Ji, J Yang, Y Li, and M Guan

Subjects

Peanut agglutinin, Male, Cell Survival, Cryopreservation, Flow cytometry, chemistry.chemical_compound, Endocrinology, medicine, Animals, Propidium iodide, Fluorescein, Acrosome, Fluorescent Dyes, biology, medicine.diagnostic_test, Flow Cytometry, Sperm, Fluorescence, Molecular biology, Macaca mulatta, Spermatozoa, chemistry, Immunology, biology.protein, Benzimidazoles, Propidium, Semen Preservation

Abstract

Many fluorescent probes excited by visible light have been used to assess sperm quality by flow cytometry. Developing a viability evaluation method using UV excited stains would be useful for multiparameter analysis of sperm function. This investigation was conducted to determine the efficacy of Hoechst 33342 (H342) and propidium iodide (PI) dual staining for evaluating rhesus monkey sperm viability through use of flow cytometry and excited by a single UV laser. The results showed that the live cells stained only with H342 strongly correlated with expected sperm viability, and flow cytometric analyses were highly correlated with fluorescence microscopic observation. Using H342/PI/SYBR-14 triple staining method, it was found that the live/dead sperm distributions were completely concordant in both H342/PI and SYBR-14/PI assays. In addition, this dual staining was extended with fluorescein isothiocyanate-conjugated peanut agglutinin (FITC-PNA) to simultaneously analyze viability and acrosome integrity of sperm cryopreserved using two different extenders, TTE and TEST, and indicated that TTE offered better preservation of plasma and acrosome integrity than TEST. Therefore, the H342/PI dual staining provides an accurate technique for evaluating viability of rhesus monkey sperm and should be valuable for multiparameter flow cytometric analysis of sperm function.

Published

2005

21. A 5.0mW 0dBm FSK transmitter for 315/433 MHz ISM applications in 0.25 μm CMOS

Author

J. Crols, W. Rens, and N. Boom

Subjects

Phase-locked loop, Physics, Narrowband, Frequency-shift keying, CMOS, business.industry, Modulation, Low-power electronics, Transmitter, Electrical engineering, business, Power (physics)

Abstract

An ultra-low power multi-channel narrowband FSK transmitter has been developed that operates in the 315/433 MHz bands for ISM applications and consumes only 5.0 mW at 1.3 V for an output power of 0 dBm. For an output power of -10 dBm the combination of the minimum power supply (0.9 V) and maximal data rate (100 kbps) leads to an energy consumption of less than 17 nJ/bit. The transmitter has a direct PLL modulation architecture using a /spl Delta//spl Sigma/ fractional-N synthesizer. The IC is implemented in a 0.25 /spl mu/m CMOS process and occupies 4.8 mm/sup 2/.

Published

2004

22. A 2.5 Gbps - 3.125 Gbps multi-core serial-link transceiver in 0.13 μm CMOS

Author

T. Geurts, Y. Segawa, S. Kashiwakura, W. Rens, and J. Crols

Subjects

Phase-locked loop, Engineering, Voltage-controlled oscillator, CMOS, business.industry, Transmitter, SerDes, Electronic engineering, Master clock, Transceiver, business, Computer hardware, Jitter

Abstract

A multi-rate serdes macro that is targeting multi-channel applications has been developed in 0.13 /spl mu/m. A low-jitter LC VCO PLL can provide the master clock for up to 16 receive and transmit modules. Specific provisions for operation at different data rates are present. The receive module operates at full rate. Comma detection and 8b/10b coding are present. The transmitter has a measured output jitter of 8.1 ps rms at 2.5 Gbps. The receiver has a measured intrinsic jitter tolerance of 0.75 UI. Power consumption for the PLL is 40 mW, a receive and transmit pair consumes 100 mW.

Published

2004

23. Head area measurements of dead, live, X- and Y-bearing bovine spermatozoa

Author

M. E. Edvi, A. Hidas, I. Gustavsson, András Kovács, T. Révay, S.-Z. Nagy, and W. Rens

Subjects

Male, Photomicrography, endocrine system, X Chromosome, Cell Survival, Reproductive technology, Biology, Giemsa stain, Cryopreservation, Andrology, chemistry.chemical_compound, Endocrinology, Y Chromosome, Genetics, Image Processing, Computer-Assisted, Animals, Acrosome, Molecular Biology, reproductive and urinary physiology, In Situ Hybridization, Fluorescence, Cell Size, Cell Death, urogenital system, Embryo culture, Anatomy, Staining, Reproductive Medicine, chemistry, Sperm Head, Animal Science and Zoology, Trypan blue, Cattle, Spermatogenesis, Developmental Biology, Biotechnology

Abstract

The head area of bull spermatozoa was measured after viability and acrosome staining using trypan blue and Giemsa stains, followed by X- and Y-chromosome-specific fluorescence in situ hybridisation (FISH). The former staining made possible the categorisation of cells according to morphology and membrane integrity, whereas the latter allowed distinction of spermatozoa bearing X- and Y-chromosomes. Individual spermatozoa could be followed during the consecutive steps of staining, measurement and FISH. Using a high-resolution digital imaging system and measurement software, the head area of more than 3000 cells of five bulls was determined precisely. In all bulls, morphologically normal, viable cells with intact acrosomes were significantly smaller than dead cells with damaged acrosomes. No significant difference in the head area between X- and Y-chromosome-bearing viable, acrosome-intact spermatozoa was found in individual bulls. However, significant between-bull differences were detected in all cell categories.

Published

2004

24. Detection of water buffalo sex chromosomes in spermatozoa by fluorescence in situ hybridization

Author

T, Révay, A, Kovács, G A, Presicce, W, Rens, and I, Gustavsson

Subjects

Male, Sex Chromosomes, Buffaloes, Animals, DNA Probes, Spermatozoa, In Situ Hybridization, Fluorescence

Abstract

In order to identify X- and Y-bearing spermatozoa in water buffalo by fluorescence in situ hybridization (FISH), some available probes of closely related species were examined. An X- and Y-specific probe set, made from flow sorted yak chromosomes, labelled in somatic metaphases of water buffalo the whole X and Y, respectively, except their centromere regions. A cattle Y-chromosome repeat sequence (BC1.2) showed strong signal on the telomere region of the buffalo Y-chromosome, demonstrating the evolutionary conservation of this locus in water buffalo. In hybridization experiments with spermatozoa from five buffaloes, the yak X-Y paint set demonstrated clear signals in more than 92% (46.8% X and 45.8% Y) of the cells. Using the cattle Y-chromosome specific BC1.2 probe, clear hybridization signal was detected in more than 48% of the cells. Statistical analysis showed that there was no significant difference between bulls or from the expected 50 : 50 ratio of X- and Y-bearing cells. The probes presented here are reliable to assess separation of X- and Y-bearing spermatozoa.

Published

2003

25. Conserved chromosome segments in Hylobates hoolock revealed by human and H. leucogenys paint probes

Author

W, Nie, W, Rens, J, Wang, and F, Yang

Subjects

Recombination, Genetic, Color, Physical Chromosome Mapping, Sensitivity and Specificity, Chromosomes, Translocation, Genetic, Chromosome Banding, Chromosome Painting, Evolution, Molecular, Karyotyping, Sequence Homology, Nucleic Acid, Animals, Chromosomes, Human, Humans, Hylobates, Female, Lymphocytes, DNA Probes, Conserved Sequence

Abstract

A complete comparative chromosome map of the white-browed gibbon (Hylobates hoolock, 2n = 38), white-cheeked gibbon (Hylobates leucogenys, 2n = 52), and human has been established by hybridising H. leucogenys chromosome-specific paints and human 24-colour paints onto H. hoolock metaphase chromosomes. In the 18 H. hoolock autosomes, we identified 62 conserved segments that showed DNA homology to regions of the 25 H. leucogenys autosomes. Numerous interchromosomal rearrangements differentiate the karyotypes of H. leucogenys and H. hoolock. Only H. hoolock chromosome 10 showed homology to one entire autosome of H. leucogenys. The hybridisation of human 24-colour paints not only confirmed most of the chromosome correspondences between human and H. hoolock established previously but also helped to correct five erroneous assignments and revealed three new segments. Our results demonstrate that the karyotypes of the extant gibbons have arisen mainly through extensive translocation events and that the karyotype of H. hoolock more closely resembles the ancestral karyotype of Hylobates, rather than the karyotype of H. leucogenys.

Published

2001

26. Karyotype relationships between distantly related marsupials from South America and Australia

Author

W, Rens, P C, O'Brien, F, Yang, N, Solanky, P, Perelman, A S, Graphodatsky, M W, Ferguson, M, Svartman, A A, De Leo, J A, Graves, and M A, Ferguson-Smith

Subjects

Evolution, Molecular, Male, Marsupialia, Karyotyping, Sequence Homology, Nucleic Acid, Australia, Animals, South America, Chromosomes, Chromosome Banding, Chromosome Painting

Abstract

Reciprocal chromosome painting and G-banding were used to compare the karyotypes of three Australian marsupials (Sminthopsis crassicaudata, Macropus eugenii, Trichosurus vulpecula) and one South American marsupial (Monodelphis domestica). The results revealed only a limited number of rearrangements between these species and that the four karyotypes can be described as different combinations of fifteen conserved segments. Five chromosomes are totally conserved between M. domestica (pairs 1, 2, 5, 8 and the X) and the presumed 2n = 14 Australian ancestral karyotype, while M. domestica pairs 3 and 6 and 4 and 7 would have been involved in fusion/fission rearrangements. Chromosome comparisons are presented in a chromosome homology map. Although the species studied diverged 70 million years ago, the karyotype of Monodelphis domestica is highly conserved in relation to those of Australian marsupials.

Published

2001

27. Chromosomal painting detects non-random chromosome arrangement in dasyurid marsupial sperm

Author

I K, Greaves, M, Svartman, M, Wakefield, D, Taggart, A, De Leo, M A, Ferguson-Smith, W, Rens, P C, O'Brien, L, Voullaire, M, Westerman, and J A, Graves

Subjects

Male, Mice, Marsupialia, Animals, Sperm Head, Spermatozoa, Chromosomes, Chromosome Painting

Abstract

Chromosome arrangements have been studied in metaphase and interphase somatic cells and in sperm of many animal species, but there are conflicting data and it is still not clear whether chromosomes are arranged randomly or non-randomly. We used chromosome painting to reveal the positions of chromosomes in marsupial sperm. Marsupials are ideally suited for these studies because they have only a few large chromosomes. Here, we show that chromosomes occupy fixed positions in the immature and mature sperm of Sminthopsis crassicaudata. We suggest that the non-random arrangement of chromosomes in marsupial sperm may be important in establishing chromosome arrangement and patterns of gene activity within the developing embryo.

Published

2001

28. An X-Y paint set and sperm FISH protocol that can be used for validation of cattle sperm separation procedures

Author

W, Rens, F, Yang, G, Welch, S, Revell, P C, O'Brien, N, Solanky, L A, Johnson, and M A, Ferguson Smith

Subjects

Male, Sex Determination Analysis, X Chromosome, Y Chromosome, Animals, Cattle, Cell Separation, DNA, Flow Cytometry, Spermatozoa, Cells, Cultured, In Situ Hybridization, Fluorescence, Chromosome Painting

Abstract

X and Y chromosome paints were developed from sorted yak chromosomes for sexing cattle spermatozoa. Clear hybridization signals were obtained for every spermatozoon using a modified sperm decondensation protocol and fluorescence in situ hybridization (FISH). The procedure was evaluated using the established Beltsville sperm sexing technology, which separates spermatozoa by flow cytometry into X- and Y-bearing fractions. Close agreement was found between the assessment of sperm separation by flow cytometry and by FISH with the X-Y paint set. The FISH method is a simple, reliable and robust procedure for assessing the effectiveness of separation of X and Y spermatozoa.

Published

2001

29. Complete homology maps of the rabbit (Oryctolagus cuniculus) and human by reciprocal chromosome painting

Author

R, Korstanje, P C, O'Brien, F, Yang, W, Rens, A A, Bosma, H A, van Lith, L F, van Zutphen, and M A, Ferguson-Smith

Subjects

Male, Base Sequence, Swine, Chromosome Mapping, Flow Cytometry, Polymerase Chain Reaction, Chromosome Painting, Muntjacs, Species Specificity, Karyotyping, Cats, Animals, Humans, Cattle, Female, Rabbits, Conserved Sequence, In Situ Hybridization, Fluorescence

Abstract

Fluorescence in situ hybridization (FISH) was used to construct a homology map to analyse the extent of evolutionary conservation of chromosome segments between human and rabbit (Oryctolagus cuniculus, 2n = 44). Chromosome-specific probes were established by bivariate fluorescence activated flow sorting followed by degenerate oligonucleotide-primed PCR (DOP-PCR). Painting of rabbit probes to human chromosomes and vice versa allowed a detailed analysis of the homology between these species. All rabbit chromosome paints, except for the Y paint, hybridized to human chromosomes. All human chromosome paints, except for the Y paint, hybridized to rabbit chromosomes. The results obtained revealed extensive genome conservation between the two species. Rabbit chromosomes 12, 19 and X were found to be completely homologous to human chromosomes 6, 17 and X, respectively. All other human chromosomes were homologous to two or sometimes three rabbit chromosomes. Many conserved chromosome segments found previously in other mammals (e.g. cat, pig, cattle, Indian muntjac) were also found to be conserved in rabbit chromosomes.

Published

1999

30. Karyotype relationships between four distantly related marsupials revealed by reciprocal chromosome painting

Author

W, Rens, P C, O'Brien, F, Yang, J A, Graves, and M A, Ferguson-Smith

Subjects

Marsupialia, Karyotyping, Image Processing, Computer-Assisted, Animals, Chromosome Mapping, DNA Probes, Flow Cytometry, Fluoresceins, In Situ Hybridization, Fluorescence, Phylogeny, Cell Line, Chromosome Banding, Chromosome Painting

Abstract

Marsupial karyotypes have shown extensive conservation even between distantly related groups with a high diversity of life forms and reproductive biology. Banding analysis has been the main test for assessing their homologies and chromosome rearrangements. More recently, cross-species reciprocal chromosome painting has been developed and applied to several mammalian species and has shown homologies and rearrangements not revealed by banding analysis. Karyotype relationships between four marsupial species, Sminthopsis crassicaudata, Potorous tridactylus, Trichosurus vulpecula and Macropus eugenii, which are from different families in two orders, were investigated and presented in the form of comparative chromosome maps. These show that only a limited number of chromosomal rearrangements have occurred during their evolution. A karyotype phylogeny of the four marsupials was derived from these maps. A comparison between published gene location and the comparative chromosome maps for these species is presented and inconsistencies with previous gene mapping data indicated.

Published

1999

31. A novel nozzle for more efficient sperm orientation to improve sorting efficiency of X and Y chromosome-bearing sperm

Author

W, Rens, G R, Welch, and L A, Johnson

Subjects

Male, Mice, X Chromosome, Swine, Y Chromosome, Animals, Humans, Cattle, Rabbits, Spermatozoa

Abstract

Efficient high-resolution detection of DNA for flow cytometric sorting of X and Y chromosome-bearing sperm is dependent on effectively orientating the sperm head to the laser beam in orthogonally configured flow systems. Normally, a beveled needle is required to enlarge the fraction of properly orientated sperm (flat side facing the laser beam). In this report, a modification to a standard jet-in-air nozzle for improved sperm orientation is presented. Inside the modified nozzle (novel nozzle), orientation forces are applied lower in the nozzle than in the current beveled injection needle system. The nozzle was tested with sperm heads from several species. This study shows that use of the nozzle to orientate cattle, swine, rabbit, mouse, and human sperm effectively improves the percentage of sperm that are properly oriented. The percentage of sperm heads oriented by use of the former system (beveled needle) ranges around 30% for most species. With the newly designed nozzle, that percentage ranges around 60%. At least a twofold increase in analysis is achieved. It was found that, unlike results with the beveled needle, the percentage of properly oriented sperm was independent of the sample rate. The introduced nozzle is a significant improvement over the beveled needle system for the analysis and sorting of sperm on the basis of DNA content. In addition to the improvement in sorted sperm production brought about by the novel nozzle when fitted to standard-speed cell sorters, it clearly also has significant potential for improving the efficiency of the Beltsville Sperm Sexing Technology for separating X and Y chromosome-bearing sperm when adapted to high-speed cell-sorting systems.

Published

1998

32. 43rd Biennial American Cytogenetics Conference. May 4-7, 2014. The Omni Grove Park Inn. Asheville, North Carolina, USA: Abstracts

Author

Hanne Tittelbach, M. Miyachi, P.A. Lima-Filho, V. Genualdo, W. Rens, Gopakumar Radhakrishnan, C. Nishida, M.B. Cioffi, W.F. Molina, Alfredo Pauciullo, Alessandra Iannuzzi, Berndt Schulze, H. Hosoi, Karl Mehnert, Ahmed B. Hamid, Clara Iannuzzi, Darren K. Griffin, V. Zukin, Nadezda Kosyakova, M. Röser, Fedora Stipoljev, Shaymaa S. Hussein, H. Yamane, Marcelo de Bello Cioffi, Dagmar Huhle, Monika Ziegler, L. Kratochvíl, D. Mykytenko, Hannes Spittel, K. Shiwaku, Peter Kozlowski, Y. Matsuda, Katharina Kreskowski, Satz Mengensatzproduktion, J. Schneider, Annelore Junge, Faezeh Vasheghani, L. Spinenko, Thomas Martin, Xiaobo Fan, Petra Musilova, M. Rovatsos, Domenico Incarnato, L.A.C. Bertollo, Angela Perucatti, S. Ishishita, L. Pylyp, G. Winterfeld, Jiri Rubes, N. Kakazu, K. Yamada, Laura Rodríguez, Catherine Sarri, Mehmet Ali Ergun, K. Perner, Thomas Liehr, Mariela Militaru, G.W.W.F. Costa, M. Pokorná, Florian Kubek, Druckerei Stückle, Marianne Volleth, and Elisabeth Klein

Subjects

medicine.medical_specialty, Genetics, Cytogenetics, medicine, Biology, Molecular Biology, Archaeology, Genetics (clinical)

Published

2014

33. Flow cytometric detection of chromosome abnormalities by measuring centromeric index, DNA content, and DNA base composition

Author

W, Rens, G A, Boschman, J M, Hoovers, E M, Manders, R M, Slater, J, Stap, and J A, Aten

Subjects

Chromosome Aberrations, Base Composition, Carcinoma, Transitional Cell, X Chromosome, Chromosomes, Human, Pair 11, Centromere, DNA, DNA, Neoplasm, Flow Cytometry, Wilms Tumor, Urinary Bladder Neoplasms, Data Interpretation, Statistical, Karyotyping, Tumor Cells, Cultured, Humans, Aniridia, Cell Line, Transformed

Abstract

This paper highlights two improvements of the on-line centromeric index (CI) analysis for the detection of chromosome abnormalities. On-line CI versus DNA content analysis of an EBV-transformed cell line, with a deletion (11)(p13p15.1), of a patient with aniridia and Wilms' tumour demonstrates the first improvement of the method of on-line CI analysis for flow karyotyping and sorting; a reciprocal translocation, insertion, or deletion can, when the cell type contains not more than a few of these types of abnormalities, be traced to the p-arm or q-arm of the relevant chromosome. On-line CI analysis was also performed with chromosomes isolated from a transitional cell carcinoma of the bladder. Cytogenetic analysis of this cell line showed numerous chromosomal abnormalities. Chromosomes of this cell line were also karyotyped by bivariate flow cytometry using a different set of parameters: Hoechst 33,258 fluorescence intensity (HOfl) versus chromomycin A3 fluorescence intensity (CAfl). A comparison of these results reveals the second improvement of the CI method for the detection of chromosome abnormalities; bivariate analysis of CI versus propidium fluorescence (PIfl) are complementary to bivariate analysis of HOfl versus CAfl. Chromosomes with distributions that fuse together in the HO/CA flow karyotype may be distinguished as individual peaks on the basis of their CI values.

Published

1994

34. Slit-scanning technique using standard cell sorter instruments for analyzing and sorting nonacrocentric human chromosomes, including small ones

Author

M. E. Jakobs, C. H. Van Oven, W. Rens, Jan Stap, Jacob A. Aten, and Other departments

Subjects

Genetics, Biophysics, Sorting, Flow cell, Karyotype, Cell Separation, DNA, Cell Biology, Hematology, Biology, Flow Cytometry, Molecular biology, Slit, Pathology and Forensic Medicine, Cell sorter, Endocrinology, Isolated population, Karyotyping, Centromere, Chromosomes, Human, Humans, Cells, Cultured, Laser beams

Abstract

We have investigated the performance of two types of standard flow cell sorter instruments, a System 50 Cytofluorograph and a FACSTar PLUS cell sorter, for the on-line centromeric index (CI) analysis of human chromosomes. To optimize the results, we improved the detection efficiency for centromeres in two ways. A higher efficiency was obtained first by elongation of the chromosomes and second by introducing a high resolution lens system for laser beam focusing. In the two-parameter flow karyotype of CI and DNA content of human chromosomes, distinct peaks are produced not only by the larger chromosomes 1--8 and X, but by the smaller nonacrocentric chromosomes 9–12 and 16–20 as well. As the chromosomes 9–12 cannot be distinguished by other flow karyotyping methods, we discriminated and sorted chromosomes 12 and 10 from 9 and 11 to investigate the capacity for the separation of chromosomes in this group. A purity of at least 90% was achieved; in the isolated population the fraction chromosomes 12 was 55%; the remaining 45% were chromosomes 10 (40%) and unidentifiable chromosomes (5%). © 1994 Wiley-Liss, Inc.

Published

1994

35. Time-optimized analysis of slit-scan chromosome profiles on a general-purpose personal computer

Author

Michael Hausmann, Jacob A. Aten, W. Rens, Christoph Cremer, Rainer Heilig, and Other departments

Subjects

Statistics and Probability, Computer science, Biochemistry, Online Systems, Chromosomes, Flow cytometry, Cricetulus, Microcomputers, Cricetinae, medicine, Dosimetry, Animals, Chromosomes, Human, Humans, Molecular Biology, Metaphase, medicine.diagnostic_test, Computer program, Flow Cytometry, Slit, Computer Science Applications, Data set, Computational Mathematics, Computational Theory and Mathematics, Flow (mathematics), General purpose, Personal computer, Algorithm, Algorithms

Abstract

Slit-scan flow cytometry provides a method to analyze large numbers of metaphase chromosomes in a relatively short time due to morphological features. The high detection rate requires fast computing for on-line analysis. Up to now, this has been achieved using special-purpose computers, parallel systems or other complex hardware. Here, we describe an algorithm that can be implemented on a general-purpose personal computer. Digitized chromosome profiles can be classified by several criteria especially for the detection of chromosome abnormalities in biological dosimetry. A data set of approximately 4600 profiles was used. Programming in assembler results in an average computing time of about 600 microseconds per profile. Thus on-line evaluation of slit-scanning data appears to become feasible for many flow cytometers running nowadays.

Published

1993

36. Effectiveness of pulse-shape criteria for the selection of dicentric chromosomes by slit-scan flow cytometry and sorting

Author

W, Rens, C H, Van Oven, J, Stap, and J A, Aten

Subjects

Chromosome Aberrations, Image Processing, Computer-Assisted, Animals, Flow Cytometry, Cell Line

Abstract

A method was developed to detect dicentric chromosomes by slit-scan flow cytometry. The two centromeres of dicentric chromosomes are represented by the two dips in the trimodal fluorescence profile. A trimodal profile can, however, also be generated by aggregates of chromosomes. We tested the effectiveness of slit-scan profile criteria that were applied to discriminate between trimodal profiles generated by dicentrics and trimodal profiles generated by artefacts. A Profile-Dip Counter (PDC) module was designed that can assess, in real time, the number of dips in slit-scan profiles. The PDC module was used in combination with a Cytofluorograph System 50 cell sorter for slit-scan sorting of chromosomes prepared from irradiated V79 cells. Chromosomes corresponding to trimodal profiles were sorted individually onto slides for subsequent visual inspection by fluorescence microscopy. The isolated chromosomes were stretched by treatment with trypsin to increase the efficiency for centromere detection. When fixed with glutaraldehyde, chromosomes could be sorted intact on slides. We found that trimodal profiles are generated by dicentric chromosomes as well as by monocentric and aggregated chromosomes. When stringent pulse-shape criteria were applied for the selection of profiles, the yield of dicentric chromosomes was 70% of the sorted chromosomes.

Published

1993

37. Identification of a tumor marker chromosome by flow sorting, DNA amplification in vitro, and in situ hybridization of the amplified product

Author

AY van der Veen, G A Boschman, Jan Osinga, Jacob A. Aten, Rosalyn Slater, W. Rens, Charles H.C.M. Buys, and Other departments

Subjects

Genetic Markers, Cancer Research, medicine.medical_specialty, Marker chromosome, Chromosomes, Human, Pair 20, Biology, Polymerase Chain Reaction, Translocation, Genetic, Tumor Cells, Cultured, Genetics, medicine, Humans, Metaphase, In Situ Hybridization, Fluorescence, Chromosome 7 (human), Carcinoma, Transitional Cell, Chromosomes, Human, Pair 13, Cytogenetics, Chromosome, DNA, Neoplasm, Aneuploidy, Flow Cytometry, Chromosome microdissection, Molecular biology, Urinary Bladder Neoplasms, Genetic marker, Chromosome 20

Abstract

A method combining flow sorting and molecular cytogenetic techniques for the identification of unknown marker chromosomes is described. In this study, the bladder tumor cell line J82 was used, which was known to carry a marker chromosome of the size of chromosome 7 in every cell. From the cytogenetic analysis of Q-banded metaphase cells, it was shown to be composed of approximately 40% presumably the greater part of chromosome 20 and for the rest microscopically unidentifiable material. This marker chromosome was found using flow cytometric analysis to form an independent peak and hence was suitable for isolation using dual-parameter sorting after staining with Hoechst 33258 and chromomycin A3. Subsequently, the marker was isolated by dual-parameter sorting. DNA amplification of 300 isolated chromosomes by polymerase chain reaction (PCR) using the Alu-primer Bk33 and the LINES-primer LH5 was carried out. After purification of the amplified product, a yield of 5 microns of DNA was obtained. The DNA was labelled using Bio-11-dUTP and applied to human lymphocyte metaphase cells in a suppressive in situ hybridization procedure. Fluorescence was visible over chromosome 20 and over the distal one-half of 6p. Together the fluorescent regions accounted for only approximately 60% of the marker length, indicating a possible duplication of chromosome 20 material. This was confirmed by applying bicolor in situ hybridization using chromosome 6- and 20-specific DNA libraries to metaphase cells of the J82 cells.

Published

1993

38. Subject Index Vol. 92, 2001

Author

N.W. Richards, M. Gahr, L.J. Coignet, G. Novelli, C. Hansen, D.L. Gumucio, A. Geurts van Kessel, N. Tommerup, L.M. Gulluyan, N. Serakıncı, M. Sancandi, K. Friis Henriksen, B. Dallapiccola, N.A. Jenkins, M. Shichiri, G.P. Di Meo, I. Gustavsson, B.R. Olsen, S.X. Liang, L. Kutschke, J.M. Moalic, G. Beck, A. Baldini, P. Wieacker, D.J. Gilbert, R.-D. Wegner, F. Sangiuolo, W.D. Phillips, J. Fanburg-Smith, A.S. Graphodatsky, C.P. Popescu, M. Kuro-o, G. Stranzinger, J.A. Kennell, M. Schmid, E. Paditz, Y. Obara, H. Kuiper, W. El-Rifai, Y. Xie, J. Wang, S. Shulenin, A.T. Remaley, S. Thomas, K. Ogura, A. Botta, J. Koch, K. Tsuchiya, B.S. Milne, P.D. Rathjen, C. Broccardo, A. Bulfone, C. Drögemüller, S-I. Kawada, S. Knuutila, J.J.M. van Groningen, J. Rathjen, T. Isobe, G. Palumbo, M. Fava, H.R. Treutlein, M.A. Ferguson-Smith, S. Fojo, L. Iannuzzi, P. Denèfle, C. Roumier, M. Wilbrink, K. Engel, T. Krieg, K.-M. Debatin, G. Merkx, G. Chimini, I. Ceccherini, Y. Mao, F. Pardo-Manuel de Villena, M. Rosier, F. Yang, N.D. Ebenezer, M.G. Mattei, P.C.M. O’Brien, M. Miettinen, A. Mincheva, W. Schwaeble, D.S. Gallagher, R. Sauer, D. Fukushi, S. Galiègue-Zouitina, Y. Matsuda, B. Pedersen, M. Berloco, A. Kuroiwa, S. Cirera, E.P. Cribiu, S. Imbeaud, Z. Zhou, F. Amati, C. Sapienza, Diederik R.H. de Bruijn, M.A.J. Weterman, A. Ratti, W. Wang, B. Brewer, V. Jurecic, C. Mas, K. Matsumoto, C.G. Scheuerpflug, N. Serdukova, V.T. Volobouev, A. Vaiman, M. Simonneau, S. Neubauer, J. Womack, C. Auffray, M.-D. Devignes, M.A. Lee-Kirsch, F. Jakob, K.J. Portbury, R. Allikmets, H. Mehenni, T. Ogura, R. Cinti, O. Distl, W. Zhao, M.-F. Luciani, S.E. Antonarakis, E. Conti, L. Granjon, L. Naudin, M.R. Speicher, R.B. Voyle, C.M. Owczarek, Y.-A. Lee, F. Guimiot, R. Zoorob, H. Hayes, S. Schmutz, L.M. Schriml, J. Dai, C. Chelala, E. Kater-Baats, P.J. Hertzog, P.E. Schaner, J. Kere, B. Sicard, A.G. Marneros, I. Arnould, S. Keindorff, E. Reichenberger, P. Perelman, F. Bourgeois, P. Lichter, R.M. Hope, I. Nanda, M. Eleveld, R. Tang, C.Y. Gregory-Evans, S. Cui, W. Nie, Y. Huang, A. Hoffmann, M. Fredholm, C. Prades, M.P. Hildebrand, B. Jordan, D. Di Berardino, M. Bak, I. Jentsch, J. Rubes, A. Rösen-Wolff, S. Kiuru-Kuhlefelt, M. Dean, T. Otoguro, S. Halford, C. Lafargue, R. Ravazzolo, M. Bozzali, W.O. Bauer, G. Gradl, S.S. Bhattacharya, Q. Jiang, S. Murray, M. van Rooijen, K. Ying, J. Osorio, X. Huang, M. Stumm, I. Matera, T. Leeb, W. Rens, N.B. Atkin, A. Eggen, I. Kola, C. Stover, A. Pizzuti, R. Wieser, N.G. Copeland, and B. Levacher

Subjects

Genetics, Index (economics), Subject (documents), Social science, Biology, Molecular Biology, Genetics (clinical)

Published

2001

39. Semi-automated detection of aberrant chromosomes in bivariate flow karyotypes

Author

Jacob A. Aten, G A Boschman, Erik M. M. Manders, Rosalyn Slater, W. Rens, and Other departments

Subjects

Abnormal chromosomes, Biophysics, Tumor cells, Bivariate analysis, Biology, Fluorescence, Pathology and Forensic Medicine, chemistry.chemical_compound, Neuroblastoma, Endocrinology, Image Processing, Computer-Assisted, Tumor Cells, Cultured, Humans, Natural variability, Cells, Cultured, Genetics, Chromosome Aberrations, Chromomycins, Chromosome, Karyotype, Cell Biology, Hematology, DNA, DNA, Neoplasm, Fibroblasts, Flow Cytometry, Molecular biology, chemistry, Healthy individuals, Karyotyping, Chromomycin A3

Abstract

A method is described that is designed to compare, in a standardized procedure, bivariate flow karyotypes of Hoechst 33258 (HO)/ Chromomycin A3 (CA) stained human chromosomes from cells with aberrations with a reference flow karyotype of normal chromosomes. In addition to uniform normalization of normal and abnormal flow karyotypes, the main purpose is detection of structurally abnormal chromosomes in often complex karyotypes of tumor cells. The method, which has been implemented in a computer program, consists of a comparison of individual chromosome peaks with the positions of peaks in the flow karyotype constituted by normal chromosomes and takes into account the natural variability in base composition of normal chromosomes among healthy individuals. Flowkaryotypes are normalized using an iterative fitting procedure, using corrections for (1) amplification of HO and CA fluorescence, (2) cross-talk between the fluorescence signals of HO and CA, and (3) offset of the HO and CA origin. Flow karyotypes of two cell lines, one with a simple deletion and the other with more complex karyotypic changes, were analyzed. The results of flow analysis were found to be in general agreement with the cytogenetic analysis of quinacrine banded karyotypes.

Published

1992

40. Subject Index Vol. 86, 1999

Author

K. Smith, T. Shiina, E. Karayianni, N. Katsanis, C-C. Hu, D. Quincey, W. Wuyts, Giovanna Grimaldi, C. Alberti, M. Kaneko, L. Viggiano, D.S. Gerhard, Jet Bliek, M. Hatakeyama, M. Athanasiou, J. Cruces, R. Carrozzo, Rogier Versteeg, Barbara R. DuPont, P. Lustenberger, Manfred Gessler, X. Reveles, D.G. Stathakis, T. Taguchi, Y.-O. Kim, G. Arrigo, K. Hoehn, N. Sato, E. Gentile, J. Strovel, S. Grimmond, K. Okumura, R. Koike, Y. Franke, T. Leeb, L.J. Conner, A. Veronese, M. James, H. Satoh, H. Narimatsu, F. Yang, R. Taramelli, V. Bhide, N.G. Copeland, P. Taschner, H. Kawakami, C. Staib, W. Mann, E. Schuuring, S. Osborne Lawrence, H. Inoko, J. Kalla, I. Nanda, T. Torii, K. Georgas, P.A. Ioannou, P.G. Gallagher, A. Fogli, P.J. Yarowsky, T. Aso, C.G. Jakobsen, T. Serikawa, M. Negrini, K. Amimoto, F. Grummt, T. Kitamura, C. Lemercier, S.F. Konieczny, U. Mahlknecht, N. Spieker, J.L. Marsh, Y.-J. Kang, T. Haaf, G.M. Maniatis, K. Yamada, K. De Boulle, T. Kozaki, L. Burridge, S. Nakamura, U. Sohn, G. Pottier, L. Martins, A.A. Bosma, Nicoletta Archidiacono, T. Hardt, L. Reid, M. Rosati, G. Barbanti-Brodano, J. Stamberg, Grant C. Sellar, C. Desmaze, G.N. Hendy, H. Maruyama, L.V. Debelenko, I.E. Scheffler, H.C. Au, E. Verdin, O. Marcu, C. Roussakis, D. Hoelzer, M. Zollo, A. Strub, E. Li, K. Kikuchi, S.-H. Kim, D. Carbonnelle, B. Zabel, P. Grossfeld, P.C.M. O’Brien, W. Van Hul, T. Kudo, N.A. Jenkins, L.A. Pérez Jurado, F. Parente, S.E. Hayes, F. Hosoda, R.J. Peoples, M. Hattori, A. Tunnacliffe, O. Zuffardi, M. Gordon, S. Giglio, J. Harris, N.A. Manjunath, C.L. Pin, R. Korstanje, Peter Little, K. Yuri, A. De Paepe, G. Chenevix-Trench, H.-H. Ropers, J.P. Simmer, J.J. Bitgood, A. Calender, C. Lo Nigro, J.T. Mascarello, C.N. Sprung, M. Ohki, Mariano Rocchi, M.C. Yoshida, J. Justesen, T. Liehr, T. Miyachi, S. Takai, G.F. Carle, K. Ladjali-Mohammedi, T. Thangarajah, L. Canaff, Marcel M.A.M. Mannens, M. Tixier-Boichard, N. Saitou, M. Selkirk, C. Turc-Carel, M. Horie, C.M. Croce, C. Berger, M. Lepke, S. Forbes, B. Gawin, H. Himmelbauer, M.A. Ferguson-Smith, T. Iizuka, Glen A. Evans, N. Van Roy, Melissa H. Little, Y.-K. Wang, M. Kinebuchi, P.J. Willems, M.G. Denis, T. Mattina, H.-Z. Chen, U. Francke, S.-H. Park, T.-L. Huh, L.F.M. van Zutphen, B. Brenig, M. Okano, P.A. Martin-DeLeon, M.-D. Devignes, N. Miyasaka, S.-Y. Park, Matthew Breen, H.-J. Koh, X. Deng, H.A. van Lith, L. Sabatier, T. Kuramoto, M. Schmid, C. Talbot, C. Magnanini, S. Sabbioni, J.P. Murnane, R. Favier, L.E. Stramm, J.-Å. Gustafsson, L.A. Rethy, W. Rens, K. Krejčí, L.L. Hansen, Shin-ichiro Takebayashi, H. Hummerich, R. Bucala, Y. Shi, D.H. Spathas, C. Jacquot, F.A. Ponce de León, G.P. Holmes, A. Matsuura, V. Orphanos, M. Trubia, S. Stilgenbauer, P. Gaudray, T.K. Watanabe, D.J. Gilbert, P. Bray-Ward, G. Weber, J. Koch, K. Kitada, H. Iwasaki, G. Gaudray, S. Katabami, S. Raynaud, T. Watanabe, C. Morelli, Veronica van Heyningen, Franki Speleman, P. Zisimopoulou, N. Serakıncı, S.A.N. Goldstein, and D. Masson

Subjects

Genetics, Index (economics), Subject (documents), Social science, Biology, Molecular Biology, Genetics (clinical)

Published

1999

41. UKCCCR guidelines for the use of cell lines in cancer research

Author

D.S. Gerhard, L. Viggiano, M. Kaneko, Rogier Versteeg, Barbara R. DuPont, P.A. Ioannou, R. Koike, R. Taramelli, D. Carbonnelle, C. Lemercier, M. Hattori, S. Takai, Peter Little, V. Bhide, P. Taschner, J. Strovel, M. Trubia, Manfred Gessler, A. Tunnacliffe, S. Stilgenbauer, E. Li, C. Staib, S.E. Hayes, D.G. Stathakis, S.-H. Park, F. Hosoda, N.A. Manjunath, A.A. Bosma, H. Maruyama, M. Selkirk, Y. Franke, G.M. Maniatis, T. Mattina, L. Sabatier, M. Lepke, S. Sabbioni, Nicoletta Archidiacono, A. Fogli, P.J. Yarowsky, K. Georgas, D. Quincey, L.V. Debelenko, S. Forbes, H.A. van Lith, U. Mahlknecht, H. Kawakami, W. Wuyts, Mariano Rocchi, U. Sohn, G.P. Holmes, J. Stamberg, A. Matsuura, T. Kuramoto, Shin-ichiro Takebayashi, N. Serakıncı, Matthew Breen, V. Orphanos, W. Rens, K. De Boulle, M. Athanasiou, S.-H. Kim, S. Grimmond, P. Lustenberger, M. Schmid, H. Narimatsu, Y.-O. Kim, R.J. Peoples, M. Rosati, J. Harris, K. Yuri, J.L. Marsh, H.C. Au, Y.-J. Kang, P. Gaudray, E. Schuuring, A. De Paepe, M. Zollo, J. Cruces, K. Krejčí, K. Hoehn, H. Inoko, T.K. Watanabe, C. Lo Nigro, M.C. Yoshida, J. Justesen, T. Kudo, Jet Bliek, C. Morelli, D.J. Gilbert, P. Bray-Ward, Franki Speleman, T. Torii, C.L. Pin, R. Korstanje, G. Chenevix-Trench, M. Horie, C.M. Croce, G. Weber, P.G. Gallagher, T. Kitamura, N. Sato, J. Koch, S.A.N. Goldstein, C.N. Sprung, G. Pottier, M. Gordon, S. Giglio, K. Kitada, H. Hummerich, M. Kinebuchi, T. Leeb, L.J. Conner, K. Amimoto, P. Zisimopoulou, Marcel M.A.M. Mannens, B. Brenig, Grant C. Sellar, M. James, A. Veronese, H.-J. Koh, A. Calender, C. Roussakis, M.A. Ferguson-Smith, Y.-K. Wang, Teijiro Aso, H. Iwasaki, P.A. Martin-DeLeon, H. Satoh, E. Gentile, M.-D. Devignes, P. Grossfeld, G. Gaudray, N. Miyasaka, L.L. Hansen, O. Marcu, X. Deng, S. Raynaud, F. Grummt, T. Haaf, T. Watanabe, R. Bucala, Y. Shi, C.G. Jakobsen, K. Yamada, X. Reveles, F. Yang, T. Liehr, L. Martins, N. Spieker, D.H. Spathas, C. Jacquot, F.A. Ponce de León, L. Canaff, N. Saitou, Veronica van Heyningen, L.F.M. van Zutphen, Masaki Okano, N.A. Jenkins, P.J. Willems, W. Mann, M.G. Denis, S. Osborne Lawrence, K. Smith, S. Nakamura, Katsuzumi Okumura, T. Shiina, J.P. Murnane, E. Karayianni, M. Tixier-Boichard, I.E. Scheffler, R. Favier, L.E. Stramm, C. Berger, B. Zabel, J.-Å. Gustafsson, Melissa H. Little, L.A. Rethy, T. Kozaki, F. Parente, L. Burridge, S. Katabami, D. Masson, K. Kikuchi, N. Katsanis, C-C. Hu, R. Carrozzo, T. Taguchi, C. Talbot, C. Magnanini, L. Reid, G. Arrigo, N.G. Copeland, I. Nanda, J.T. Mascarello, T. Miyachi, C. Turc-Carel, Glen A. Evans, L.A. Pérez Jurado, N. Van Roy, D. Hoelzer, M. Ohki, G.N. Hendy, C. Desmaze, H.-Z. Chen, P.C.M. O’Brien, W. Van Hul, G.F. Carle, H.-H. Ropers, S.-Y. Park, Masanori Hatakeyama, C. Alberti, S.F. Konieczny, T. Iizuka, O. Zuffardi, J.P. Simmer, J.J. Bitgood, J. Kalla, K. Ladjali-Mohammedi, T. Serikawa, M. Negrini, T. Thangarajah, B. Gawin, H. Himmelbauer, Giovanna Grimaldi, T. Hardt, G. Barbanti-Brodano, E. Verdin, A. Strub, U. Francke, and T.-L. Huh

Subjects

Evolutionary biology, Cell culture, Genetics, Biology, Molecular Biology, Genetics (clinical), Human genetics

Published

1999

42. Sex determination in platypus and echidna: autosomal location of SOX3 confirms the absence of SRY from monotremes.

Author

M. Wallis, P. Waters, M. Delbridge, A. Pask, W. Rens, M. Ferguson-Smith, and J. Graves

Abstract

Abstract  In eutherian (‘placental’) mammals, sex is determined by the presence or absence of the Y chromosome-borne gene SRY, which triggers testis determination. Marsupials also have a Y-borne SRY gene, implying that this mechanism is ancestral to therians, the SRY gene having diverged from its X-borne homologue SOX3 at least 180 million years ago. The rare exceptions have clearly lost and replaced the SRY mechanism recently. Other vertebrate classes have a variety of sex-determining mechanisms, but none shares the therian SRY-driven XX female:XY male system. In monotreme mammals (platypus and echidna), which branched from the therian lineage 210 million years ago, no orthologue of SRY has been found. In this study we show that its partner SOX3 is autosomal in platypus and echidna, mapping among human X chromosome orthologues to platypus chromosome 6, and to the homologous chromosome 16 in echidna. The autosomal localization of SOX3 in monotreme mammals, as well as non-mammal vertebrates, implies that SRY is absent in Prototheria and evolved later in the therian lineage 210–180 million years ago. Sex determination in platypus and echidna must therefore depend on another male-determining gene(s) on the Y chromosomes, or on the different dosage of a gene(s) on the X chromosomes. [ABSTRACT FROM AUTHOR]

Published

2007

43. A procedure for image enhancement in chromosome painting.

Author

W. Rens, K. Moderegger, H. Skelton, O. Clarke, V. Trifonov, and M. Ferguson-Smith

Subjects

CHROMOSOMES, CELL nuclei, GENETICS, ORGANELLES

Abstract

An image enhancement procedure was developed to produce high-contrast chromosome paint images. This procedure is well suited for images where brightness–contrast enhancement is subjective. Three examples are given to show that the procedure is very efficient to remove non-specific hybridization signals from the chromosome paint image. Chromosomes of roe deer contain large amounts of centromeric heterochromatic DNA. Echidna chromosomes show specific heterochromatic DNA distributed over several chromosomes. In both cases chromosome identification was hampered by bright heterochromatic regions. The enhancement tool was fully used in cross-species chromosome painting, which is the last example. The three examples show that the procedure is very simple to use and removes background in a controlled and defined manner. [ABSTRACT FROM AUTHOR]

Published

2006

44. Reciprocal chromosome painting between two South American bats: Carollia brevicauda and Phyllostomus hastatus (Phyllostomidae, Chiroptera).

Author

J. C. Pieczarka, C. Y. Nagamachi, P. C. M. OBrien, F. Yang, W. Rens, R. M. S. Barros, R. C. R. Noronha, J. Rissino, E. H. C. de Oliveira, and M. A. Ferguson-Smith

Subjects

PHYLLOSTOMIDAE, GENETICS, PHYLLOSTOMUS, MAMMALS

Abstract

Abstract The Neotropical Phyllostomidae family is the third largest in the order Chiroptera, with 56 genera and 140 species. Most researchers accept this family as monophyletic but its species are anatomically diverse and complex, leading to disagreement on its systematics and evolutionary relationships. Most of the genera of Phyllostomidae have highly conserved karyotypes but with intense intergeneric variability, which makes any comparative analysis using classical banding difficult. The use of chromosome painting is a modern way of genomic comparison on the cytological level, and will clarify the intense intergenus chromosomal variability in Phyllostomidae. Whole chromosome probes of species were produced as a tool for evolutionary studies in this family from two species from different subfamilies, Phyllostomus hastatus and Carollia brevicauda, which have large morphological and chromosomal differences, and these probes were used in reciprocal chromosome painting. The hybridization of the Phyllostomus probes on the Carollia genome revealed 24 conserved segments, while the Carollia probes on the Phyllostomus genome detected 26 segments. Many chromosome rearrangements have occurred during the divergence of these two genera. The sequence of events suggested a large number of rearrangements during the differentiation of the genera followed by high chromosomal stability within each genus. [ABSTRACT FROM AUTHOR]

Published

2005

45. Multicolor Fluorescence In Situ Hybridization (FISH) Approaches for Simultaneous Analysis of the Entire Human Genome.

Author

Zhang C, Cerveira E, Rens W, Yang F, and Lee C

Subjects

Humans, Chromosome Painting methods, Genome, Human, Genomics methods, High-Throughput Nucleotide Sequencing methods, In Situ Hybridization, Fluorescence methods, Spectral Karyotyping methods

Abstract

Analysis of the organization of the human genome is vital for understanding genetic diversity, human evolution, and disease pathogenesis. A number of approaches, such as multicolor fluorescence in situ hybridization (FISH) assays, cytogenomic microarray (CMA), and next-generation sequencing (NGS) technologies, are available for simultaneous analysis of the entire human genome. Multicolor FISH-based spectral karyotyping (SKY), multiplex FISH (M-FISH), and Rx-FISH may provide rapid identification of interchromosomal and intrachromosomal rearrangements as well as the origin of unidentified extrachromosomal elements. Recent advances in molecular cytogenetics have made it possible to efficiently examine the entire human genome in a single experiment at much higher resolution and specificity using CMA and NGS technologies. Here, we present an overview of the approaches available for genome-wide analyses. © 2018 by John Wiley & Sons, Inc., (© 2018 John Wiley & Sons, Inc.)

Published

2018

46. Targeted deletion of a 170-kb cluster of LINE-1 repeats and implications for regional control.

Author

Soares ML, Edwards CA, Dearden FL, Ferrón SR, Curran S, Corish JA, Rancourt RC, Allen SE, Charalambous M, Ferguson-Smith MA, Rens W, Adams DJ, and Ferguson-Smith AC

Subjects

Animals, Mice, Male, Female, Embryonic Stem Cells metabolism, Mice, Inbred C57BL, Long Interspersed Nucleotide Elements, Genomic Imprinting, Sequence Deletion

Abstract

Approximately half the mammalian genome is composed of repetitive sequences, and accumulating evidence suggests that some may have an impact on genome function. Here, we characterized a large array class of repeats of long-interspersed elements (LINE-1). Although widely distributed in mammals, locations of such arrays are species specific. Using targeted deletion, we asked whether a 170-kb LINE-1 array located at a mouse imprinted domain might function as a modulator of local transcriptional control. The LINE-1 array is lamina associated in differentiated ES cells consistent with its AT-richness, and although imprinting occurs both proximally and distally to the array, active LINE-1 transcripts within the tract are biallelically expressed. Upon deletion of the array, no perturbation of imprinting was observed, and abnormal phenotypes were not detected in maternal or paternal heterozygous or homozygous mutant mice. The array does not shield nonimprinted genes in the vicinity from local imprinting control. Reduced neural expression of protein-coding genes observed upon paternal transmission of the deletion is likely due to the removal of a brain-specific enhancer embedded within the LINE array. Our findings suggest that presence of a 170-kb LINE-1 array reflects the tolerance of the site for repeat insertion rather than an important genomic function in normal development., (© 2018 Soares et al.; Published by Cold Spring Harbor Laboratory Press.)

Published

2018

47. New insights into sex chromosome evolution in anole lizards (Reptilia, Dactyloidae).

Author

Giovannotti M, Trifonov VA, Paoletti A, Kichigin IG, O'Brien PC, Kasai F, Giovagnoli G, Ng BL, Ruggeri P, Cerioni PN, Splendiani A, Pereira JC, Olmo E, Rens W, Caputo Barucchi V, and Ferguson-Smith MA

Subjects

Animals, Chromosome Banding, Chromosome Mapping, Chromosome Painting, Female, Genes, Mitochondrial, In Situ Hybridization, Fluorescence, Karyotype, Karyotyping, Male, Recombination, Genetic, Evolution, Molecular, Lizards genetics, Sex Chromosomes

Abstract

Anoles are a clade of iguanian lizards that underwent an extensive radiation between 125 and 65 million years ago. Their karyotypes show wide variation in diploid number spanning from 26 (Anolis evermanni) to 44 (A. insolitus). This chromosomal variation involves their sex chromosomes, ranging from simple systems (XX/XY), with heterochromosomes represented by either micro- or macrochromosomes, to multiple systems (X 1 X 1 X 2 X 2 /X 1 X 2 Y). Here, for the first time, the homology relationships of sex chromosomes have been investigated in nine anole lizards at the whole chromosome level. Cross-species chromosome painting using sex chromosome paints from A. carolinensis, Ctenonotus pogus and Norops sagrei and gene mapping of X-linked genes demonstrated that the anole ancestral sex chromosome system constituted by microchromosomes is retained in all the species with the ancestral karyotype (2n = 36, 12 macro- and 24 microchromosomes). On the contrary, species with a derived karyotype, namely those belonging to genera Ctenonotus and Norops, show a series of rearrangements (fusions/fissions) involving autosomes/microchromosomes that led to the formation of their current sex chromosome systems. These results demonstrate that different autosomes were involved in translocations with sex chromosomes in closely related lineages of anole lizards and that several sequential microautosome/sex chromosome fusions lead to a remarkable increase in size of Norops sagrei sex chromosomes.

Published

2017

48. Evolutionary dynamics of Anolis sex chromosomes revealed by sequencing of flow sorting-derived microchromosome-specific DNA.

Author

Kichigin IG, Giovannotti M, Makunin AI, Ng BL, Kabilov MR, Tupikin AE, Barucchi VC, Splendiani A, Ruggeri P, Rens W, O'Brien PC, Ferguson-Smith MA, Graphodatsky AS, and Trifonov VA

Subjects

Animals, Chromosome Mapping, DNA isolation & purification, Evolution, Molecular, Microdissection, High-Throughput Nucleotide Sequencing methods, Reptiles genetics, Sequence Analysis, DNA methods, Sex Chromosomes genetics

Abstract

Squamate reptiles show a striking diversity in modes of sex determination, including both genetic (XY or ZW) and temperature-dependent sex determination systems. The genomes of only a handful of species have been sequenced, analyzed and assembled including the genome of Anolis carolinensis. Despite a high genome coverage, only macrochromosomes of A. carolinensis were assembled whereas the content of most microchromosomes remained unclear. Most of the Anolis species have homomorphic XY sex chromosome system. However, some species have large heteromorphic XY chromosomes (e.g., A. sagrei) and even multiple sex chromosomes systems (e.g. A. pogus), that were shown to be derived from fusions of the ancestral XY with microautosomes. We applied next generation sequencing of flow sorting-derived chromosome-specific DNA pools to characterize the content and composition of microchromosomes in A. carolinensis and A. sagrei. Comparative analysis of sequenced chromosome-specific DNA pools revealed that the A. sagrei XY sex chromosomes contain regions homologous to several microautosomes of A. carolinensis. We suggest that the sex chromosomes of A. sagrei are derived by fusions of the ancestral sex chromosome with three microautosomes and subsequent loss of some genetic content on the Y chromosome.

Published

2016

49. Low rate of interchromosomal rearrangements during old radiation of gekkotan lizards (Squamata: Gekkota).

Author

Johnson Pokorná M, Trifonov VA, Rens W, Ferguson-Smith MA, and Kratochvíl L

Subjects

Animals, Chromosome Painting, Evolution, Molecular, In Situ Hybridization, Fluorescence, Karyotype, Lizards classification, Metaphase genetics, Phylogeny, Chromosomes, Lizards genetics, Recombination, Genetic, Translocation, Genetic

Abstract

Gekkotan lizards are a highly specious (∼1600 described species) clade of squamate lizards with nearly cosmopolitan distribution in warmer areas. The clade is primarily nocturnal and forms an ecologically dominant part of the world nocturnal herpetofauna. However, molecular cytogenetic methods to study the evolution of karyotypes have not been widely applied in geckos. Our aim here was to uncover the extent of chromosomal rearrangements across the whole group Gekkota and to search for putative synapomorphies supporting the newly proposed phylogenetic relationships within this clade. We applied cross-species chromosome painting with the recently derived whole-chromosomal probes from the gekkonid species Gekko japonicus to members of the major gekkotan lineages. We included members of the families Diplodactylidae, Carphodactylidae, Pygopodidae, Eublepharidae, Phyllodactylidae and Gekkonidae. Our study demonstrates relatively high chromosome conservatism across the ancient group of gekkotan lizards. We documented that many changes in chromosomal shape across geckos can be attributed to intrachromosomal rearrangements. The documented rearrangements are not totally in agreement with the recently newly erected family Phyllodactylidae. The results also pointed to homoplasy, particularly in the reuse of chromosome breakpoints, in the evolution of gecko karyotypes.

Published

2015

50. A ZZ/ZW sex chromosome system in the thick-tailed Gecko ( Underwoodisaurus milii; Squamata: Gekkota: Carphodactylidae), a member of the ancient gecko lineage.

Author

Pokorná M, Rens W, Rovatsos M, and Kratochvíl L

Subjects

Animals, Evolution, Molecular, Female, Male, Phylogeny, Chromosome Banding veterinary, Lizards classification, Lizards genetics, Sex Chromosomes, Sex Determination Processes genetics

Abstract

Geckos (Gekkota) are a highly diversified group of lizards with an exceptional diversity in sex-determining systems. Despite this intriguing documented variability, data on sex determination in many lineages is still scarce. Here, we document the previously overlooked heteromorphic ZZ/ZW sex chromosomes in the thick-tailed gecko, Underwoodisaurus milii, a member of the ancient lineage of pygopodoid geckos. The finding of female heterogamety within pygopodoid geckos was unexpected, as until now only male heterogamety and environmental sex determination have been reported in this group, and female heterogamety was known only in distantly related gecko families separated from the pygopodoid geckos around 150 million years ago. The W chromosome in U. milii is highly heterochromatic and contains a large number of telomeric-like repeats comparable to around 50% of all telomeric-like sequences present in male genomes. The accumulation of these repeats might have been responsible for the considerable size expansion of the W chromosome in comparison to the Z chromosome. The heteromorphic ZZ/ZW sex chromosomes with accumulated telomeric-like repeats in the thick-tailed geckos further illustrate the exceptional diversity of sex-determining systems in geckos and add important information to our understanding of the evolution and phylogeny of sex-determining systems in reptiles., (© 2014 S. Karger AG, Basel.)

Published

2014