The lowest diploid number in Testudines: Banding patterns, telomeric and 45S rDNA FISH in Peltocephalus dumerilianus, 2n = 26 and FN = 52 (Pleurodira, Podocnemididae)

Ventura, Karen; Moreira, Camila N; Moretti, Renata; Yonenag-Yassuda, Yatiyo; Rodrigues, Miguel T

doi:10.1590/S1415-47572014000100011

Abstract

The karyotype of the big-headed Amazon River turtle, Peltocephalus dumerilianus, is characterized based on a sample of seven juveniles from Reserva Biológica do Rio Trombetas, Pará State, Brazil (1°30' S, 56°34' W). Here we present the first results on GTG and CBG-banding patterns, Ag-NOR staining and FISH, with telomeric and 45S rDNA sequences as probes. A cytogenetic comparison with related Podocnemidae is also provided.

big-headed Amazon River turtle; molecular cytogenetics; Pelomedusoides

SHORT COMMUNICATION

The lowest diploid number in Testudines: Banding patterns, telomeric and 45S rDNA FISH in Peltocephalus dumerilianus, 2n = 26 and FN = 52 (Pleurodira, Podocnemididae)

Karen Ventura^I; Camila N Moreira^I; Renata Moretti^II; Yatiyo Yonenag-Yassuda^I; Miguel T Rodrigues^II

^IDepartamento de Genética e Biologia Evolutiva, Instituto de Biociências, Universidade de São Paulo, São Paulo, SP, Brazil.

^IIDepartamento de Zoologia, Instituto de Biociências, Universidade de São Paulo, São Paulo, SP, Brazil.

^{Send correspondence to} Send correspondence to Yatiyo Yonenag-Yassuda. Departamento de Genética e Biologia Evolutiva, Instituto de Biociências, Universidade de São Paulo, Rua do Matão 277, 05508-090 São Paulo, SP, Brazil. E-mail: yyassuda@ib.usp.br

ABSTRACT

The karyotype of the big-headed Amazon River turtle, Peltocephalus dumerilianus, is characterized based on a sample of seven juveniles from Reserva Biológica do Rio Trombetas, Pará State, Brazil (1°30' S, 56°34' W). Here we present the first results on GTG and CBG-banding patterns, Ag-NOR staining and FISH, with telomeric and 45S rDNA sequences as probes. A cytogenetic comparison with related Podocnemidae is also provided.

Key words: big-headed Amazon River turtle, molecular cytogenetics, Pelomedusoides.

The big-headed side-neck river turtle, Peltocephalus dumerilianus (Schweigger, 1812), occurs in the Amazon region and belongs to the superfamily Pelomedusoides (approximately 24 living species), which comprises the families Pelomedusidae, with two living genera: Pelomedusa and Pelusios represented by one, and at least 15 species, respectively; and Podocnemididae, with three living genera: the monotypic Erymnochelys and Peltocephalus, and Podocnemis comprising six species (Ayres et al., 1969; Vitt and Caldwell, 2009). In Podocnemididae cytogenetic data are scarce and based mostly on conventional staining. The Podocnemis and Erymnochelys species (P. erythrocephala, P. expansa, P. lewyana, P. sextuberculata, P. unifilis, P. vogli and E. madagascariensis) present a diploid number (2n) of 28, with a karyotype composed of five macrochromosomes (M) and nine microchromosomes (m) (Ayres et al., 1969; Huang and Fred Clark 1969; Rhodin et al., 1978; Bull and Legler, 1980; Fantin and Monjeló, 2011; Gunski et al., 2013). The exception is Peltocephalus dumerilianus that presents 2n = 26 (FN = 52) with 4 M and 9m, the lowest diploid number in Testudines (ranging from 2n = 26 to 2n = 96) (Ayres et al., 1969; Bull and Legler, 1980). The available cytogenetic data for this species report a karyotype that is similar to those of other Podocnemididae, in which differentiated sex chromosomes are absent and a conspicuous secondary constriction is observed on the proximal region of chromosome 1p (Ortiz et al., 2005; Fantin and Monjeló, 2011).

Herein, based on a sample of seven juveniles from Reserva Biológica do Rio Trombetas (1°30' S, 56°34' W), Amazonian forest of Pará State, Brazil, the karyotype of P. dumerillianus was characterized for the first time using routine differential techniques, such as GTG, CBGbanding and Ag-NOR staining (Seabright, 1971; Sumner, 1972; Howell and Black, 1980, with modifications) and molecular tools employing FISH with telomeric and 45S rDNA sequences as probes in metaphases obtained from in vivo bone marrow preparations (Ford and Hamerton, 1956).

Briefly, FISH with telomeric probes was performed using a Telomere PNA FISH Kit/FITC (K 5325, Dako) following the manufacturer's protocol. The FISH procedures for the 45S rDNA were followed the method adapted by Cabral-de-Mello et al. (2010). The 45S rDNA probes were biotinylated by nick-translation (Invitrogen, San Diego, CA, USA) and detected with avidin-Cy3 (Life-Technologies). All slides were counterstained with DAPI diluted in Vectashield (Vector) and analyzed using a fluorescence microscope (Zeiss Axiophot) equipped with software for image capture Isis karyotyping system, MetaSystems).

For all individuals, at least 20 metaphases were analyzed for determining the 2n = 26 and FN = 52 karyotype, as described by Ayres et al., 1969, with a conspicuous secondary constriction on pair 1 (Figure 1A). GTG-banding patterns allowed the identification and the pairing of all chromosomes (Figure 1B). CBG-bands were tenuous at the pericentromeric region of most pairs, except for pair 1 which exhibited a large block of constitutive heterochromatin at the secondary constriction region. Ag-NOR staining also showed positive NORs at the same region on chromosome 1p (Figure 1C). The FISH analysis showed telomeric signals restricted to the ends of the chromosomes (Figure 1D), and 45S rDNA sites were localized exclusively at the secondary constriction region of pair 1 (Figure 1E).

In Podocnemididae, the NOR-bearing pair was identified in three of the six living species of Podocnemis (P. expansa, P. sextuberculata and P. vogli) (Ortiz et al., 2005; Fantin and Monjeló, 2011) and the staining region corresponds, as in Peltocephalus, to the secondary constriction of chromosome 1, characterizing until now a conserved condition for the family. On the other hand, CBG-banding patterns are quite specific when compared to the chromosomes of Podocnemis vogli which present larger amount of heterochromatin distributed at pericentromeric and interstitial regions of the chromosomes, as described by Ortiz et al. (2005). Both data suggest that despite the similar diploid number, chromosomal morphology and the NOR-bearing pair, the CBG-banding pattern allows to identify speciesspecific karyotypes, revealing chromosomal differences that accumulated during karyotype evolution. At present, a more adequate interspecific chromosomal comparison is not possible, as the differences in chromosomes condensation presented in the published data render unreliable the establishment of similarities in banding patterns. Future chromosomal comparisons using CBG and GTG-banding patterns, as well as mapping of the 45S rDNA and telomeric sites in other representatives, could be useful to identify the rearrangements involved in karyotypic differentiation of Podocnemididae.

Acknowledgments

We thank Diogo C Cabral-de-Mello for providing the 45S rDNA probes and his valuable help with the hybridization experiments. Grants from Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq), Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) and Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP 2009/54300-0 and 2013/20188-4) made this work possible.

Received: November 1, 2013;

Accepted: November 28, 2013.

Associate Editor: Marcelo Guerra

All the content of the journal, except where otherwise noted, is licensed under a Creative Commons License CC BY-NC.

Ayres M, Sampaio MM, Barros RMS, Dias LB and Cunha OR (1969) A karyological study of turtles from the Brazilian Amazon River. Cytogenetics 8:401-409.
Bull JJ and Legler JM (1980) Karyotypes of sidenecked turtles (Testudines, Pleurodira). Can J Zool 58:828-884.
Cabral-de-Mello DC, Moura RC and Martins C (2010) Chromosomal mapping of repetitive DNAs in the beetle Dichotomius geminatusprovides the first evidence for an association of 5S rRNA and histone H3 genes in insects, and repetitive DNA similarity between the B chromosome and A complement. Heredity 104:393-400.
Fantin C and Monjeló LAS (2011) Cytogenetic studies in Podocnemis expansa and Podocnemis sextuberculata (Testudines, Podocnemididae), turtles of the Brazilian Amazon. Caryologia 2:154-157.
Ford CE and Hamerton JL (1956) A colchicine hypotonic- citrate squash sequence for mammalian chromosome. Stain Techn 31:247-251.
Gunski RJ, Cunha IS, Degrandi TM, LedesmaMand Garnero AV (2013) Cytogenetic comparison of Podocnemis expansa and Podocnemis inifilis: A case of inversion and duplication involving constitutive heterochromatin. Genet Mol Biol 36:353-356.
Howell WM and Black DA (1980) Controlled silver- staining of nucleous organizer regions with a protective colloidal developer: A 1-step method. Experientia 36:1014-1015.
Huang CC and Fred Clark H (1969) Chromosome studies of the cultured cells of two species of Side-Necked Turtles (Podocnemis unifilis and P. expansa). Chromosoma 26:245-253.
Ortiz ML, Rodríguez PA and Bueno ML (2005) Caracterización citogenética de la tortuga sabanera Podocnemis vogli (Reptilia, Testudinata, Podocnemididae). Acta Biol Colomb 1:19-33.
Rhodin AGJ, Mittermeier RA, Gardner AL and Medem F (1978) Karyotypic analysis of the Podocnemis turtles. Copeia 4:723-728.
Seabright M (1971) A rapid banding technique for human chromosomes. Lancet. 2:971-972.
Sumner AT (1972) A simple technique for demonstrating centromeric heterocromatin. Exp Cell Res 75:304- 306.
Vitt LJ and Caldwell JP (2009) Herpetology. 3rd edition. Academic Press, Burlington 697 pp.

Send correspondence to

Yatiyo Yonenag-Yassuda.

Departamento de Genética e Biologia Evolutiva, Instituto de Biociências,

Universidade de São Paulo,

Rua do Matão 277,

05508-090 São Paulo, SP, Brazil.

E-mail:

yyassuda@ib.usp.br

Publication Dates

Publication in this collection
24 Mar 2014
Date of issue
2014

History

Received
01 Nov 2013
Accepted
28 Nov 2013

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] Ayres M, Sampaio MM, Barros RMS, Dias LB and Cunha OR (1969) A karyological study of turtles from the Brazilian Amazon River. Cytogenetics 8:401-409.

[2] Bull JJ and Legler JM (1980) Karyotypes of sidenecked turtles (Testudines, Pleurodira). Can J Zool 58:828-884.

[3] Cabral-de-Mello DC, Moura RC and Martins C (2010) Chromosomal mapping of repetitive DNAs in the beetle Dichotomius geminatusprovides the first evidence for an association of 5S rRNA and histone H3 genes in insects, and repetitive DNA similarity between the B chromosome and A complement. Heredity 104:393-400.

[4] Fantin C and Monjeló LAS (2011) Cytogenetic studies in Podocnemis expansa and Podocnemis sextuberculata (Testudines, Podocnemididae), turtles of the Brazilian Amazon. Caryologia 2:154-157.

[5] Ford CE and Hamerton JL (1956) A colchicine hypotonic- citrate squash sequence for mammalian chromosome. Stain Techn 31:247-251.

[6] Gunski RJ, Cunha IS, Degrandi TM, LedesmaMand Garnero AV (2013) Cytogenetic comparison of Podocnemis expansa and Podocnemis inifilis: A case of inversion and duplication involving constitutive heterochromatin. Genet Mol Biol 36:353-356.

[7] Howell WM and Black DA (1980) Controlled silver- staining of nucleous organizer regions with a protective colloidal developer: A 1-step method. Experientia 36:1014-1015.

[8] Huang CC and Fred Clark H (1969) Chromosome studies of the cultured cells of two species of Side-Necked Turtles (Podocnemis unifilis and P. expansa). Chromosoma 26:245-253.

[9] Ortiz ML, Rodríguez PA and Bueno ML (2005) Caracterización citogenética de la tortuga sabanera Podocnemis vogli (Reptilia, Testudinata, Podocnemididae). Acta Biol Colomb 1:19-33.

[10] Rhodin AGJ, Mittermeier RA, Gardner AL and Medem F (1978) Karyotypic analysis of the Podocnemis turtles. Copeia 4:723-728.

[11] Seabright M (1971) A rapid banding technique for human chromosomes. Lancet. 2:971-972.

[12] Sumner AT (1972) A simple technique for demonstrating centromeric heterocromatin. Exp Cell Res 75:304- 306.

[13] Vitt LJ and Caldwell JP (2009) Herpetology. 3rd edition. Academic Press, Burlington 697 pp.

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