Chromosome evolution in dendropsophini (amphibia, anura, hylinae)

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Dendropsophini is the most species-rich tribe within Hylidae with 234 described species. Although cytogenetic information is sparse, chromosome numbers and morphology have been considered as an important character system for systematic inferences in this group. Using a diversity of standard and mole...

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Autor principal: Suárez, P.
Otros Autores: Cardozo, D., Baldo, D., Pereyra, M.O, Faivovich, J., Orrico, V.G.D, Catroli, G.F, Grabiele, M., Bernarde, P.S, Nagamachi, C.Y, Haddad, C.F.B, Pieczarka, J.C
Formato: Capítulo de libro
Lenguaje:Inglés
Publicado: 2013
Acceso en línea:Registro en Scopus
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Biblioteca Central Dr. Luis F. Leloir (FCEN) de Universidad de Buenos Aires
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100 1 |a Suárez, P. 
245 1 0 |a Chromosome evolution in dendropsophini (amphibia, anura, hylinae) 
260 |c 2013 
270 1 0 |m Suárez, P.; Laboratório de Citogenética, Instituto de Ciências Biológicas Universidade Federal Do Pará, Rua Augusto Correa Belém, PA 66075-990, Brazil; email: psuarez@ufpa.br 
506 |2 openaire  |e Política editorial 
504 |a Aguiar Jr., O., Bacci Jr., M., Lima, A.P., Rossa-Feres, D.C., Haddad, C.F.B., Recco-Pimentel, S.M., Phylogenetic relationships of Pseudis and Lysapsus (Anura, Hylidae, Hylinae) inferred from mitochondrial and nuclear gene sequences (2007) Cladistics, 23 (5), pp. 455-463. , DOI 10.1111/j.1096-0031.2007.00154.x 
504 |a Anderson, K., A karyological perspective on the monophyly of the hylid genus Osteopilus (1996) Contributions to West Indian Herpetology: A Tribute to Albert Schwartz, pp. 157-168. , Powell R, Henderson RW (eds) (Society for the Study of Amphibians and Reptiles, Ithaca) 
504 |a Barrio-Amoros, C.L., De Pascual, A.D., Mueses-Cisneros, J.J., Infante, E., Chacon, A., Hyla vigilans Solano, 1971, a second species for the genus Scarthyla, redescription and distribution in Venezuela and Colombia (2006) Zootaxa, (1349), pp. 1-18 
504 |a Beukeboom, L.W., Bewildering Bs: An impression of the 1st B-Chromosome Conference (1994) Heredity, 73 (3), pp. 328-336 
504 |a Bogart, J.P., Evolution of anuran karyotypes (1973) Evolutionary Biology of the Anurans: Contemporary Research on Major Problems, pp. 337-349. , Vial JL (ed) (University of Missouri Press, Columbia) 
504 |a Busin, C.S., Vinciprova, G., Recco-Pimentel, S.M., Chromosomal rearrangements as the source of variation in the number of chromosomes in Pseudis (Amphibia, Anura) (2001) Genetica, 110 (2), pp. 131-141. , DOI 10.1023/A:1017957716678 
504 |a Busin, C.S., Lima, A.P., De Almeida Prado, C.P., Strüssmann, C., Júnior, S.S., Recco-Pimentel, S.M., Chromosomal differentiation of populations of Lysapsus limellus limellus, L (2006) L. Bolivianus, and of Lysapsus Caraya (Hylinae, Hylidae). Micron, 37, pp. 355-362 
504 |a Busin, C.S., Andrade, G.V., Bertoldo, J., Del Grande, M.L., Uetanabaro, M., Recco-Pimentel, S.M., Cytogenetic analysis of four species of Pseudis (Anura, Hylidae), with the description of ZZ/ZW sex chromosomes in P. Tocantins (2008) Genetica, 133 (2), pp. 119-127. , DOI 10.1007/s10709-007-9189-7 
504 |a Camacho, J.P.M., Sharbel, T.F., Beukeboom, L.W., Bchromosome evolution (2000) Phil Trans R Soc Lond B Biol Sci, 355, pp. 163-178 
504 |a Cardozo, D.E., Leme, D.M., Bortoleto, J.F., Catroli, G.F., Baldo, D., Karyotypic data on 28 species of Scinax (Amphibia, Anura, Hylidae): Diversity and informative variation (2011) Copeia, 2011, pp. 251-263 
504 |a Carvalho, K.A., Garcia, P.C., Recco-Pimentel, S.M., NOR dispersion, telomeric sequence detection in centromeric regions and meiotic multivalent configurations in species of the Aplastodiscus albofrenatus group (Anura, Hylidae) (2009) Cytogenet Genome Res, 126, pp. 359-367 
504 |a Catroli, G.F., Kasahara, S., Cytogenetic data on species of the family Hylidae (Amphibia, Anura): Results and perspectives (2009) Publ UEPG Ci Biol Saúde, 15, pp. 67-86 
504 |a Cheng, C., Shtessel, L., Brady, M.M., Ahmed, S., Caenorhabditis elegans POT-2 telomere protein represses a mode of alternative lengthening of telomeres with normal telomere lengths (2012) Proc Natl Acad Sci USA, 109, pp. 7805-7810 
504 |a Duellman, W.E., Additional studies of chromosomes of anuran amphibians (1967) Syst Zool, 16, pp. 38-43 
504 |a Duellman, W.E., Hylid frogs of Middle America (1970) Monogr Mus Nat Hist Univ Kansas, 1-2, pp. 1-753 
504 |a Duellman, W.E., (2001) Hylid Frogs of Middle America, , (Society for the Study of Amphibians and Reptiles, Ithaca) 
504 |a Duellman, W.E., Cole, C.J., Studies of chromosomes of some anuran amphibians (Hylidae and Centrolenidae) (1965) Syst Zool, 14, pp. 139-143 
504 |a Faivovich, J., Haddad, C.F.B., Garcia, P.C.A., Frost, D.R., Campbell, J.A., Wheeler, W.C., Systematic review of the frog family Hylidae, with special reference to Hylinae: Phylogenetic analysis and taxonomic revision (2005) B Am Mus Nat Hist, 294, pp. 1-240 
504 |a Ferro, J.M., Marti, D.A., Bidau, C.J., Suárez, P., Nagamachi, C.Y., B chromosomes in the tree frog Hypsiboas albopunctatus (Anura: Hylidae) (2012) Herpetologica, 68, pp. 482-490 
504 |a Garda, A.A., Cannatella, D.C., Phylogeny and biogeography of paradoxical frogs (Anura, Hylidae, Pseudae) inferred from 12S and 16S mitochondrial DNA (2007) Molecular Phylogenetics and Evolution, 44 (1), pp. 104-114. , DOI 10.1016/j.ympev.2006.11.028, PII S1055790306004842 
504 |a Gaspin, C., Rami, J.-F., Lescure, B., Distribution of short interstitial telomere motifs in two plant genomes: Putative origin and function (2010) BMC Plant Biol, 10, p. 283 
504 |a Green, D.M., Structure and evolution of B chromosomes in amphibians (2004) Cytogenetic and Genome Research, 106 (2-4), pp. 235-242. , DOI 10.1159/000079293 
504 |a Green, D.M., Sessions, S.K., (1991) Amphibian Cytogenetics and Evolution, , Academic Press, San Diego 
504 |a Greilhuber, J., Loidl, J., On regularities of C-banding patterns and their possible cause (1983) Kew Chromosome Conference II, p. 344. , Brandham PE, Bennett MD (eds): (Allen & Unwin, London 
504 |a Gruber, S.L., Haddad, C.F.B., Kasahara, S., Evaluating the karyotypic diversity in species of Hyla (Anura, Hylidae) with 2n = 30 chromosomes based on the analysis of ten species (2005) Folia Biologica, 51 (3), pp. 68-75 
504 |a Gruber, S.L., Zina, J., Narimatsu, H., Haddad, C.F.B., Kasahara, S., Comparative karyotype analysis and chromosome evolution in the genus Aplastodiscus (Cophomantini, Hylinae, Hylidae) (2012) BMC Genet, 13, p. 28 
504 |a Howell, W.N., Black, D.A., Controlled silver-staining of nucleolus organizer regions with a protective colloidal developer: A 1-step method (1980) Experientia, 36, pp. 1014-1015 
504 |a Jones, N., Houben, A., B chromosomes in plants: Escapees from the A chromosome genome? (2003) Trends in Plant Science, 8 (9), pp. 417-423. , DOI 10.1016/S1360-1385(03)00187-0 
504 |a Kagansky, A., Folco, H.D., Almeida, R., Pidoux, A.L., Boukaba, A., Synthetic heterochromatin bypasses RNAi and centromeric repeats to establish functional centromeres (2009) Science, 324, pp. 1716-1719 
504 |a Kaiser, H., Mais, C., Bolaños, F., Steinlein, C., Feichtinger, W., Schmid, M., Chromosomal investigation of three Costa Rican frogs from the 30-chromosome radiation of Hyla with the description of a unique geographic variation in nucleolus organizer regions (1996) Genetica, 98, pp. 95-102 
504 |a Klappenbach, M.A., Notas herpetologicas, v (1985) Mus Hist Nat Montevideo, 11, pp. 1-23 
504 |a Levan, A., Fredga, K., Sandberg, A.A., Nomenclature for centromeric position on chromosomes (1964) Hereditas, 52, pp. 201-220 
504 |a Lovejoy, C.A., Li, W., Reisenweber, S., Thongthip, S., Bruno, J., Loss of ATRX, genome instability, and an altered DNA damage response are hallmarks of the alternative lengthening of telomeres pathway (2012) PLoS Genet, 8, pp. e1002772 
504 |a Lynch, J.D., Suarez-Mayorga, A.M., Clave ilustrada de los renacuajos en las tierras bajas al oriente de los Andes, con énfasis en Hylidae (2011) Caldasia, 33, pp. 235-270 
504 |a Medeiros, L.R., Rossa-Feres, D.C., Recco-Pimentel, S.M., Chromosomal differentiation of Hyla nana and Hyla sanborni (Anura, Hylidae) with a description of NOR polymorphism in H. Nana (2003) Journal of Heredity, 94 (2), pp. 149-154. , DOI 10.1093/jhered/esg019 
504 |a Medeiros, L.R., Rossa-Feres, D.C., Jim, J., Recco-Pimentel, S.M., B-chromosomes in two Brazilian populations of Dendropsophus nanus (Anura, Hylidae) (2006) Genetics and Molecular Biology, 29 (2), pp. 257-262. , http://www.scielo.br/scielo.php?script=sci_arttext&pid= S1415-47572006000200010&lng=en&nrm=iso&tlng=en, DOI 10.1590/S1415-47572006000200010 
504 |a Meyne, J., Baker, R.J., Hobart, H.H., Hsu, T.C., Ryder, O.A., Ward, O.G., Wiley, J.E., Moyzis, R.K., Distribution of non-telomeric sites of the (TTAGGG)(n) telomeric sequence in vertebrate chromosomes (1990) Chromosoma, 99 (1), pp. 3-10 
504 |a Nanda, I., Fugate, M., Steinlein, C., Schmid, M., Distribution of (TTAGGG)n telomeric sequences in karyotypes of the Xenopus species complex (2008) Cytogenet Genome Res, 122, pp. 396-400 
504 |a Pieczarka, J.C., Nagamachi, C.Y., Paes De Souza, A.C., Milhomem, S.S.R., De Castro, R.R., Nascimento, A.L., An adaptation to DAPI-banding to fishes chromosomes (2006) Caryologia, 59, pp. 43-46 
504 |a Pyron, R.A., Wiens, J.J., A large-scale phylogeny of Amphibia including over 2800 species, and a revised classification of extant frogs, salamanders, and caecilians (2011) Mol Phylogenet Evol, 61, pp. 543-583 
504 |a Redi, C.A., Garagna, S., Zacharias, H., Zuccotti, M., Capanna, E., The other chromatin (2001) Chromosoma, 110 (3), pp. 136-147 
504 |a Schmid, M., Steinlein, C., Bogart, J.P., Feichtinger, W., León, P., The chromosomes of terraranan frogs (2010) Insights into Vertebrate Cytogenetics. Cytogenet Genome Res, 130-131, pp. 1-568 
504 |a Schubert, I., Chromosome evolution (2007) Current Opinion in Plant Biology, 10 (2), pp. 109-115. , DOI 10.1016/j.pbi.2007.01.001, PII S1369526607000052, Genome Studies and Molecular Genetics 
504 |a Schweizer, D., Ambros, P.F., Chromosome banding: Stain combinations for specific regions (1994) Chromosome Analysis Protocols: Methods in Molecular Biology, 29, pp. 97-112. , Gosden JR (ed): (Humana Press, Totowa 
504 |a Schweizer, D., Loidl, J., A model for heterochromatin dispersion and the evolution of C-band patterns (1987) Chromosomes Today, 9, pp. 61-79. , Stahl A, Luciani JM, Vagner-Capodano AM (eds): (Allen & Unwin, London 
504 |a Sumner, A.T., A simple technique for demonstrating centromeric heterochromatin (1972) Exp Cell Res, 75, pp. 304-306 
504 |a Tsipouri, V., Schueler, M.G., Hu, S., Dutra, A., Comparative sequence analyses reveal sites of ancestral chromosomal fusions in the Indian muntjac genome (2008) Genome Biol, 9, pp. R155 
504 |a Vaquero-Sedas, M.I., Vega-Palas, M.A., On the chromatin structure of eukaryotic telomeres (2011) Epigenetics, 6, pp. 1055-1058 
504 |a Ventura, K., O'brien, P.C.M., Yonenaga-Yassuda, Y., Ferguson-Smith, M.A., Chromosome homologies of the highly rearranged karyotypes of four Akodon species (Rodentia, Cricetidae) resolved by reciprocal chromosome painting: The evolution of the lowest diploid number in rodents (2009) Chromosome Res, 17, pp. 1063-1078 
504 |a Viegas-Péquignot, E., In situ hybridization to chromosomes with biotinylated probes (1992) Situ Hybridization: A Practical Approach, pp. 137-158. , Willman DG (ed): (Oxford University Press, Oxford 
504 |a White, M.J.D., (1954) Animal Cytology and Evolution, , Cambridge University Press, Cambridge 
504 |a Wiens, J.J., Fetzner, J.W., Parkinson, C.L., Reeder, T.W., Hylid frog phylogeny and sampling strategies for speciose clades (2005) Syst Biol, 54, pp. 778-807 
504 |a Wiens, J.J., Graham, C.H., Moen, D.S., Smith, S.A., Reeder, T.W., Evolutionary and ecological causes of the latitudinal diversity gradient in hylid frogs: Treefrog trees unearth the roots of high tropical diversity (2006) American Naturalist, 168 (5), pp. 579-596. , DOI 10.1086/507882 
504 |a Wiens, J.J., Kuczynski, C.A., Hua, X., Moen, D.S., An expanded phylogeny of treefrogs (Hylidae) based on nuclear and mitochondrial sequence data (2010) Mol Phylogenet Evol, 55, pp. 871-882 
504 |a Wiley, J.E., Meyne, J., Little, M.L., Stout, J.C., Interstitial hybridization sites of the (TTAGGG)n telomeric sequence on the chromosomes of some North American hylid frogs (1992) Cytogenet Cell Genet, 61, pp. 55-57 
520 3 |a Dendropsophini is the most species-rich tribe within Hylidae with 234 described species. Although cytogenetic information is sparse, chromosome numbers and morphology have been considered as an important character system for systematic inferences in this group. Using a diversity of standard and molecular techniques, we describe the previously unknown karyotypes of the genera Xenohyla , Scarthyla and Sphaenorhynchus and provide new information on Dendropsophus and Lysapsus . Our results reveal significant karyotype diversity among Dendropsophini, with diploid chromosome numbers ranging from 2n = 22 in S. goinorum , 2n = 24 in Lysapsus , Scinax , Xenohyla , and almost all species of Sphaenorhynchus and Pseudis , 2n = 26 in S. carneus , 2n = 28 in P. cardosoi , to 2n = 30 in all known Dendropsophus species. Although nucleolar organizer regions (NORs) and C-banding patterns show a high degree of variability, NOR positions in 2n = 22, 24 and 28 karyotypes and C-banding patterns in Lysapsus and Pseudis are informative cytological markers. Interstitial telomeric sequences reveal a diploid number reduction from 24 to 22 in Scarthyla by a chromosome fusion event. The diploid number of X. truncata corroborates the character state of 2n = 30 as a synapomorphy of Dendropsophus . © 2013 S. Karger AG, Basel.  |l eng 
593 |a Departamento de Zoologia, Instituto de Biociências, Universidade de São Paulo, Brazil 
593 |a Laboratório de Biologia Celular, Instituto Butantan, Brazil 
593 |a Departamento de Zoologia, Instituto de Biociências, Universidade Estadual Paulista, São Paulo, Brazil 
593 |a Laboratório de Citogenética, Instituto de Ciências Biológicas Universidade Federal Do Pará, Rua Augusto Correa Belém, PA 66075-990, Brazil 
593 |a Laboratório de Herpetologia, Centro Multidisciplinar, Campus Floresta, Rio Branco, Brazil 
593 |a División Herpetología, Museo Argentino de Ciencias Naturales 'Bernardino Rivadavia, CONICET, Brazil 
593 |a Departamento de Biodiversidad y Biología Experimental, Facultad de Ciencias Exactas y Naturales, Universidad de Buenos Aires, Buenos Aires, Argentina 
593 |a Laboratorio de Genética Evolutiva, Instituto de Biología Subtropical, FCEQyN, Posadas, Argentina 
690 1 0 |a B CHROMOSOMES 
690 1 0 |a DENDROPSOPHINI 
690 1 0 |a HYLIDAE 
690 1 0 |a INTERSTITIAL TELOMERIC SEQUENCE 
690 1 0 |a KARYOTYPE DIVERSITY 
690 1 0 |a ANIMAL TISSUE 
690 1 0 |a ARTICLE 
690 1 0 |a C BANDING 
690 1 0 |a CHROMOSOME NOR 
690 1 0 |a CHROMOSOME STRUCTURE 
690 1 0 |a CYTOGENETICS 
690 1 0 |a DIPLOIDY 
690 1 0 |a GENETIC VARIABILITY 
690 1 0 |a HYLIDAE 
690 1 0 |a KARYOTYPE 
690 1 0 |a MOLECULAR EVOLUTION 
690 1 0 |a NONHUMAN 
690 1 0 |a PRIORITY JOURNAL 
690 1 0 |a SYNAPOMORPHY 
690 1 0 |a TELOMERE 
690 1 0 |a ANIMAL 
690 1 0 |a ANURA 
690 1 0 |a CHROMOSOME 
690 1 0 |a CHROMOSOME BANDING PATTERN 
690 1 0 |a CLASSIFICATION 
690 1 0 |a EVOLUTION 
690 1 0 |a GENETICS 
690 1 0 |a SPECIES DIFFERENCE 
690 1 0 |a ANURA 
690 1 0 |a ARTICLE 
690 1 0 |a AUTOSOME 
690 1 0 |a CHROMOSOME 
690 1 0 |a CHROMOSOME NUMBER 
690 1 0 |a CHROMOSOME PREPARATION 
690 1 0 |a DENDROPSOPHINI 
690 1 0 |a DENDROPSOPHUS 
690 1 0 |a LYSAPSUS 
690 1 0 |a SCARTHYLA 
690 1 0 |a SPHAENORHYNCHUS 
690 1 0 |a SUPERNUMERARY CHROMOSOME 
690 1 0 |a XENOHYLA 
690 1 0 |a AMPHIBIA 
690 1 0 |a ANURA 
690 1 0 |a HYLIDAE 
690 1 0 |a HYLINAE 
690 1 0 |a LYSAPSUS 
690 1 0 |a PSEUDIS 
690 1 0 |a SCARTHYLA 
690 1 0 |a SCARTHYLA GOINORUM 
690 1 0 |a SCINAX 
690 1 0 |a SPHAENORHYNCHUS 
690 1 0 |a SPHAENORHYNCHUS CARNEUS 
690 1 0 |a XENOHYLA 
690 1 0 |a XENOHYLA TRUNCATA 
690 1 0 |a AMPHIBIA 
690 1 0 |a ANURA 
690 1 0 |a HYLIDAE 
690 1 0 |a HYLINAE 
690 1 0 |a LYSAPSUS 
690 1 0 |a PSEUDIS 
690 1 0 |a SCARTHYLA 
690 1 0 |a SCARTHYLA GOINORUM 
690 1 0 |a SCINAX 
690 1 0 |a SPHAENORHYNCHUS 
690 1 0 |a XENOHYLA 
690 1 0 |a ANIMALS 
690 1 0 |a ANURA 
690 1 0 |a BIOLOGICAL EVOLUTION 
690 1 0 |a CHROMOSOME BANDING 
690 1 0 |a CHROMOSOMES 
690 1 0 |a GENETIC VARIATION 
690 1 0 |a KARYOTYPE 
690 1 0 |a NUCLEOLUS ORGANIZER REGION 
690 1 0 |a SPECIES SPECIFICITY 
700 1 |a Cardozo, D. 
700 1 |a Baldo, D. 
700 1 |a Pereyra, M.O. 
700 1 |a Faivovich, J. 
700 1 |a Orrico, V.G.D. 
700 1 |a Catroli, G.F. 
700 1 |a Grabiele, M. 
700 1 |a Bernarde, P.S. 
700 1 |a Nagamachi, C.Y. 
700 1 |a Haddad, C.F.B. 
700 1 |a Pieczarka, J.C. 
773 0 |d 2013  |g v. 141  |h pp. 295-308  |k n. 4  |p Cytogenet. Genome Res.  |x 14248581  |t Cytogenetic and Genome Research 
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856 4 0 |u https://doi.org/10.1159/000354997  |y DOI 
856 4 0 |u https://hdl.handle.net/20.500.12110/paper_14248581_v141_n4_p295_Suarez  |y Handle 
856 4 0 |u https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_14248581_v141_n4_p295_Suarez  |y Registro en la Biblioteca Digital 
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