Physical mapping of the 18S and 5S ribosomal genes in nine Characidae species (Teleostei, Characiformes)

Peres, Wellington Adriano Moreira; Bertollo, Luiz Antonio Carlos; Moreira Filho, Orlando

doi:10.1590/S1415-47572008000200009

Abstract

Characidae is one of the largest fish families of the Neotropical region, and presenting a pronounced morphological variability, certainly does not constitute a monophyletic group. The cytogenetical data also show a large chromosomal variation and can provide important information for a better understanding of the relationships between the species of this group. 18S and 5S rDNA probes were used in the present study for the chromosomal mapping in different Characidae species from the São Francisco River (Astyanax lacustris, Astyanax scabripinnis, Hasemania nana, Piabina argentea, Orthospinus franciscensis, Serrapinnus heterodon, Serrapinnus piaba and Myleus micans) and Alto Paraná (Astyanax altiparanae) basins. Species with a single pair of chromosomes bearing the nucleolar organizing regions (NORs) were identified, as well as species with multiple NORs, up to a maximum of seven 18S rDNA sites. The number of 5S rDNA site was also not constant, varying from two to eight. The mapping of the ribosomal genes was useful for the characterization and differentiation of the analyzed species.

cytogenetics; Neotropical fish; fluorescent in situ hybridization (FISH); rDNA probe

FISH CYTOGENETICS

RESEARCH ARTICLE

Physical mapping of the 18S and 5S ribosomal genes in nine Characidae species (Teleostei, Characiformes)

Wellington Adriano Moreira Peres; Luiz Antonio Carlos Bertollo; Orlando Moreira Filho

Departamento de Genética e Evolução, Universidade Federal de São Carlos, São Carlos, SP, Brazil

^{Send correspondence to} Send correspondence to: Orlando Moreira Filho Universidade Federal de São Carlos Rodovia Washington Luís km 235 Caixa Postal 676, 13565905 São Carlos, SP, Brazil Email: omfilho@ power.ufscar.br

ABSTRACT

Characidae is one of the largest fish families of the Neotropical region, and presenting a pronounced morphological variability, certainly does not constitute a monophyletic group. The cytogenetical data also show a large chromosomal variation and can provide important information for a better understanding of the relationships between the species of this group. 18S and 5S rDNA probes were used in the present study for the chromosomal mapping in different Characidae species from the São Francisco River (Astyanax lacustris, Astyanax scabripinnis, Hasemania nana, Piabina argentea, Orthospinus franciscensis, Serrapinnus heterodon, Serrapinnus piaba and Myleus micans) and Alto Paraná (Astyanax altiparanae) basins. Species with a single pair of chromosomes bearing the nucleolar organizing regions (NORs) were identified, as well as species with multiple NORs, up to a maximum of seven 18S rDNA sites. The number of 5S rDNA site was also not constant, varying from two to eight. The mapping of the ribosomal genes was useful for the characterization and differentiation of the analyzed species.

Key words: cytogenetics, Neotropical fish, fluorescent in situ hybridization (FISH), rDNA probe.

Introduction

The ribosomal genes are organized into two distinct multigenic families in eukaryotic organisms, one family comprising the 45S rDNA and the other the 5S rDNA. The repetitive 45S rDNA units are separated by nontranscribed external spacers and are composed of the 18S, 5.8S and 28S genes, which constitute the nucleolar organizing regions (NORs). NORs that were active in the preceding interphase are commonly detected by the silver nitrate staining (AgNORs). In lower vertebrates, NORs can also be evidenced by GCspecific fluorochromes such as chromomycin A₃ and mithramycin, independent of their activity, due to their GCrich nature (Schmid, 1980; Schmid and Guttenbach, 1988). Nevertheless, the use of fluorochromes may not be conclusive for NOR studies since GCrich heterochromatic regions not associated with NORs may be visualized (Souza et al., 2001) and at the same time the few 45S rDNA sites may not appear clearly (Mandrioli et al., 2001; Souza et al., 2001). Thus, the fluorescent in situ hybridization (FISH) becomes an important alternative to the study of NORs due to the higher specificity of this methodology.

The 5S ribosomal gene is a smaller DNA sequence that does not participate in the formation of the nucleolus. The repetitive 5S rDNA unit is a 120 bp sequence associated with highly variable nontranscribed spacers (Long and Dawid, 1980) which results in the large evolutionary dynamism of these genes (Williams and Strobeck, 1985). Contrary to the 45S rDNA genes, the 5S rDNA sites can only be mapped in the chromosomes using the FISH method. For this reason, the localization of the 5S rDNA sites can be obtained only for a lower number of species when compared to the localization of the NORs. Since the sequences of the 45S and 5S ribosomal genes remained greatly conserved during the evolution of fish (Fujiwara et al., 1998; Martins and Galetti Jr., 2000), probes prepared from the genome of a given species maybe used in the localization of these regions in other species.

18S and 5S rDNA probes were used in the present study for the physical mapping of these sites in the chromosomes of nine species of the family Characidae, aiming for their characterization and differentiation regarding these features, and a better understanding of the chromosomal evolution in this fish group.

Material and Methods

Myleus micans, Astyanax lacustris, A. scabripinnis, Hasemania nana, Piabina argentea, Orthospinus franciscensis, Serrapinnus piaba and S. heterodon from the São Franscisco River (Três Marias municipality, Minas Gerais State, Brazil), and Astyanax altiparanae from the Monjolinho Stream, Alto Paraná basin (São Carlos municipality, São Paulo State, Brazil) were analyzed.

The mitotic chromosomes were obtained from anterior and posterior kidney cells according to Bertollo et al. (1978) and Foresti et al. (1993). The chromosomes were classified as metacentric (m), submetacentric (sm), subtelocentric (st) and acrocentric (a), according to the arm ratio (Levan et al., 1964).

The mapping of the 18S and 5S rDNA sites in the chromosomes was performed through the fluorescent in situ hybridization (FISH) following Pinkel et al. (1986), with probes obtained from Prochilodus argenteus (Hatanaka and Galetti Jr., 2004) and Leporinus elongatus (Martins and Galetti Jr., 2001), respectively.

Results

The obtained results are summarized in Table 1. The diploid number, chromosomal formulae and the number of AgNORs of each species are based on previous karyotypic analyses of Peres (2005), whose results were not included in the present work. Astyanax altiparanae, A. lacustris, Orthospinus franciscensis and Serrapinnus heterodon presented only one pair of 18S rDNA sites located on the short arm of a subtelocentric chromosome pair (Figures 1a, b, f, h). The remaining species presented more than two sites of 18S rDNA. Astyanax scabripinnis presented five sites, three on the short arm of subtelo/acrocentric chromosomes and two on the long arm of a subtelocentric pair (Figure 1c). Hasemania nana also presented five sites, but all on submetacentric chromosomes, three on the long arms and two on the short arms (Figure 1d). Piabina argentea presented six sites on the short arm of subtelo/acrocentric chromosomes (Figure 1e). Serrapinnus piaba presented seven sites, two on the long arm of a meta/submetacentroc pair, two on the short arm of another meta/cubmetacentric pair and the rest on the short arm of three subtelo/acrocentric chromosomes (Figure 1g). Myleus micans presented seven sites, five on the short arm of subtelo/acrocentric chromosomes and two on the long arm of a metacentric pair (Figure 1i). All of the 18S rDNA sites were preferentially located in the telomeric region of the chromosomes, and only Myleus micans presented a chromosome pair with interstitial sites.

Thumbnail

The 5S rDNA sites were evidenced in the pericentromeric region of a pair of metacentric chromosomes in A. altiparanae, A. lacustris and M. micans (Figures 2a, b, ^h ). In A. scabripinnis, two sites were evidenced on a pair of metacentric chromosomes and two sites on a subtelo/acrocentric pair, all interstitial in the short arm (Figure 2c). In P. argentea, four sites were observed in the terminal region of the short arm of two chromosome pairs, one submetacentric and the other subtelo/acrocentric (Figure 2d). Four sites were identified in O. fransciscensis, two in an interstitial position on a metacentric pair and the other two in a terminal position on the short arm of a subtelo/acrocentric pair (Figure 2e). Four sites were also observed in S. heterodon, two in interstitial positions on metacentric chromosomes and two in terminal positions on the short arm of subtelo/ acrocentric chromosomes (^{Figure 2g} ). The largest number of 5S rDNA sites was observed in S. piaba, which presented eight interstitial markings on six meta/submetacentric chromosomes (Figure 2f), being also the only species to present two sites located in the same chromosome.

Discussion

Fluorescent in situ hybridization has become a much utilized tool for detecting NORs in the metaphasic chromosome complement since it can identify NORs independent of their activity in the previous interphase. This explains the occurrence of a larger number of NOR sites than those identified by the silver staining technique (AgNORs), as observed, for example, in Hoplias malabaricus (Born and Bertollo, 2000), A. scabripinnis (Ferro et al., 2001; Kavalco and MoreiraFilho, 2003), Prochilodus lineatus (Jesus and MoreiraFilho, 2003) and in the present work. Concerning the genus Astyanax, A. altiparanae and A. lacustris exhibited only one chromosome pair bearing 18S rDNA sites, while in A. scabripinnis five sites were found, confirming variability in NOR number and localization that has previously been observed in this genus. In fact, one of the largest number of NORs described for Characidae was observed in an A. scabripinnis population different from the one here analyzed, that had fifteen AgNOR sites NORs (RoconStange and AlmeidaToledo, 1993). Similarly in Serrapinnus the two analyzed species presented variation in the number of 18S rDNA sites, two in S. heterodon and seven in S. piaba.

The number and localization of the 5S rDNA sites in O. franciscensis, P. argentea, S. heterodon and S. piaba were also analyzed in the present study for the first time, in addition to a reanalysis of M. micans, A. lacustris, A. scabripinnis and A. altiparanae. Hasemania nana was the only species where mapping of these sites was not possible due to technical problems. Martins and Galetti Jr. (2001) consider that the presence of two interstitial 5S loci could represent a conserved character among the Characiformes. However, additional studies, especially in the family Characidae, have shown a large variability in the number and localization of these sites (Ferro et al., 2001; AlmeidaToledo et al., 2002; Kavalco et al., 2004; Mantovani et al., 2005; present study). Thus, the localization and/or position of 5S rDNA sites in the Characidae are as variable as the 18S rDNA sites.

The presence of two pericentromeric 5S rDNA loci in a mediumsized metacentric pair was also suggested as a putative conserved character in Astyanax (AlmeidaToledo et al., 2002; Mantovani et al., 2004). In fact, this characteristic was shared by the three species of this genus here studied. However, it is not a diagnostic characteristic for Astyanax, since it extends to species of other unrelated groups such as O. franciscensis, S. heterodon S. piaba and M. micans.

Variation in the number and localization of the 5S rDNA loci seems to be common among Astyanax species, ranging from two to eight loci in terminal as well as interstitial positions (Ferro et al., 2001; Kavalco et al., 2004; present study). Yet, the presence of syntenic 18S and 5S rDNA sites in a mediumsized metacentric pair of a few Astyanax species (AlmeidaToledo et al., 2002) does not occur in the Astyanax species here analyzed, since the 18S rDNA sites were not evidenced in any metacentric chromosome of this group. In A. altiparanae and A. lacustris, the rDNA sites seem to be located on homologous chromosomes, showing that these species are closely related. On the other hand, the larger number of rDNA sites found in A. scabripinnis suggests a more ancient evolutionary divergence for this species.

The distribution of the 5S and 18S rDNA sites may be a useful tool for the cytogenetic characterization of some species. Serrapinnus heterodon and S. piaba, for example, possess similar karyotypic organizations, practically precluding their separation through the conventional karyotype analysis (Peres, 2005). Nevertheless, the localization of the 5S and 18S rDNA sites allow their identification because S. heterodon presented a simple NOR system and four 5S rDNA loci, while S. piaba presented multiple NORs (seven loci) and eight 5S rDNA loci. Furthermore, the metacentric chromosome pair bearing the 5S rDNA presents a size heteromorphism in S. heterodon, with the largest chromosome being almost double the size of the smallest chromosome. The S. heterodon population here analyzed also presented a structural chromosome polymorphism, with the differentiation of two other cytotypes in addition to the standard one. These variations indicate that the differences between the three cytotypes must have originated through pericentric inversions related to chromosome pairs 8 and 26 (Peres, 2005). An uncommon characteristic was also observed in S. piaba, that is, the presence of two distinct 5S rDNA loci in a single chromosome. It is possible that part of the original 5S rDNA site has been transposed to another chromosome region by a paracentric inversion, as proposed for Upsilodus sp. (Kavalco et al., 2004).

The available data show a large variation in the number, localization and position of 18S and 5S rDNA sites in the genome of fishes. However, this variability can be more pronounced within some families, such as Characidae, in comparison to other families, such as Anostomidae and Bryconinae, which coincidently also show a larger karyotypic homogeneity. It is possible that this variability in the Characidae is a reflection of the polyphyletic nature of this fish group.

Acknowledgments

The authors wish to thank Dr. Yoshimi Sato (CODEVASF, Três Marias, MG) for the help in the specimen collection, and Dr. Flávio C. T. Lima for the taxonomical identification. This work was supported by FAPESP (Proc. 03/036421) and CNPq.

Received: August 21, 2006; Accepted: May 4, 2007.

Associate Editor: Lurdes Foresti de AlmeidaToledo

License information: This is an openaccess article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

AlmeidaToledo LF, OzoufCostaz C, Foresti F, Bonillo C, PortoForesti F and DanielSilva MFZ (2002) Conservation of the 5S bearing chromosome pair and colocalization with major rDNA clusters in five species of Astyanax (Pisces, Characidae). Cytogenet Genome Res 97:229233.
Bertollo LAC, Takahashi CS and MoreiraFilho O (1978) Cytotaxonomic consideration on Hoplias lacerdae (Pisces, Erythrinidae). Brazil J Genet 1:103120.
Born GG and Bertollo LAC (2000) An XX/XY sex chromosome system in a fish species, Hoplias malabaricus, with a polymorphic NORbearing X chromosome. Chrom Res 8:111118.
Ferro DAM, Néo DM, MoreiraFilho O and Bertollo LAC (2001) Nucleolar organizing regions, 18S and 5S rDNA in Astyanax scabripinnis (Pisces, Characidae): Population distribution and functional diversity. Genetica 110:5562.
Foresti F, Oliveira C and AlmeidaToledo LF (1993) A method for chromosome preparations from large specimens of fishes using in vitro short treatment with colchicine. Experientia 49:810813.
Fujiwara A, Abe S, Yamaha E, Yamazaki F and Yoshida MC (1998) Chromosomal localization and heterochromatin association of ribosomal RNA gene loci and silverstained nucleolar organizer regions in salmonid fishes. Chrom Res 6:463471.
Hatanaka T and Galetti Jr PM (2004) Mapping of the 18S and 5S ribosomal RNA genes in the fish Prochilodus argenteus, Agassiz, 1829 (Characiformes, Prochilodontidae). Genetica 122:239244.
Jesus CM and MoreiraFilho O (2003) Chromosomal location of 5S and 18S rRNA genes in Prochilodus lineatus (Characiformes, Prochilodontidae). Caryologia 56:281287.
Kavalco KF, Pazza R, Bertollo LAC and MoreiraFilho O (2004) Gene mapping of 5S rDNA sites in eight fish species from the Paraíba do Sul river basin, Brazil. Cytogenet Genome Res 106:107110.
Kavalco KF and MoreiraFilho O (2003) Cytogenetical analyses in four species of the genus Astyanax (Pisces, Characidae) from Paraíba do Sul river basin. Caryologia 54:453461.
Levan A, Fredga K and Sandberg AA (1964) Nomenclature for centromeric position on chromosomes. Hereditas 52:201220.
Long EO and David ID (1980) Repeated genes in eukaryotes. Annu Rev Biochem 49:727764.
Mandrioli M, Manicardi GC, Machella N and Caputo V (2001) Molecular and cytogenetic analysis of the goby Gobius niger (Teleostei, Gobiidae). Genetica 110:7378.
Mantovani M, Abel LDS, Mestriner CA and MoreiraFilho O (2004) Evidence of the differentiated structural arrangement of constitutive heterochromatin between two populations of Astyanax scabripinnis (Pisces, Characidae). Genet Mol Biol 27:536542.
Mantovani M, Abel LDS and Moreira Filho O (2005) Conserved 5S and variable 45S rDNA chromosomal localization revealed by FISH in Astyanax scabripinnis (Pisces, Characidae). Genetica 123:211216.
Martins C, Wasko A, Oliveira C and Wright JM (2000) Nucleotide sequence of 5S rDNA and localization of the ribosomal RNA genes to metaphase chromosomes of the tilapiine cichlid fish, Oreochromis niloticus Hereditas 133:3946.
Martins C and Galetti Jr PM (2001) Organization of 5S rDNA in species of the fish Leporinus: Two different genomic locations are characterized by distinct nontranscribed spacers. Genome 44:903910.
Peres WAM (2005) Análise da diversidade cariotípica de Characidae da bacia do São Francisco. Master Thesis, Universidade Federal de São Carlos, São Carlos.
Pinkel D, Straume T and Gray JW (1986) Cytogenetic analysis using quantitative, highsensitivity, fluorescence hybridization. Proc Natl Acad Sci USA 83:29342938.
RoconStange EA and AlmeidaToledo LF (1993) Supernumerary B chromosomes restricted to males in Astyanax scabripinnis (Pisces, Characidae). Brazil J Genet 16:601615.
Schmid M (1980) Chromosome banding in Amphibia: IV. Differentiation of GC and ATrich chromosomes regions in Anura. Chromosoma 77:83103.
Schmid M and Guttenbach M (1988) Evolutionary diversity of reverse (R) fluorescent chromosome bands in vertebrates. Chromosoma 97:101114.
Souza IL, Galián J, De La Rúa P, Bertollo LAC and MoreiraFilho O (2001) Nonrandom distribution of the GCrich heterocromatin and nuclear rDNA sites on Astyanax scabripinnis chromosomes. Cytologia 66:8591.
Williams SM and Strobeck C (1985) Sister chromatid exchange and the evolution of rDNA spacer length. J Theor Biol 116:625636.

Send correspondence to:

Orlando Moreira Filho

Universidade Federal de São Carlos

Rodovia Washington Luís km 235

Caixa Postal 676, 13565905 São Carlos, SP, Brazil

Email:

omfilho@ power.ufscar.br

Publication Dates

Publication in this collection
03 June 2008
Date of issue
2008

History

Accepted
04 May 2007
Received
21 Aug 2006

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

[1] AlmeidaToledo LF, OzoufCostaz C, Foresti F, Bonillo C, PortoForesti F and DanielSilva MFZ (2002) Conservation of the 5S bearing chromosome pair and colocalization with major rDNA clusters in five species of Astyanax (Pisces, Characidae). Cytogenet Genome Res 97:229233.

[2] Bertollo LAC, Takahashi CS and MoreiraFilho O (1978) Cytotaxonomic consideration on Hoplias lacerdae (Pisces, Erythrinidae). Brazil J Genet 1:103120.

[3] Born GG and Bertollo LAC (2000) An XX/XY sex chromosome system in a fish species, Hoplias malabaricus, with a polymorphic NORbearing X chromosome. Chrom Res 8:111118.

[4] Ferro DAM, Néo DM, MoreiraFilho O and Bertollo LAC (2001) Nucleolar organizing regions, 18S and 5S rDNA in Astyanax scabripinnis (Pisces, Characidae): Population distribution and functional diversity. Genetica 110:5562.

[5] Foresti F, Oliveira C and AlmeidaToledo LF (1993) A method for chromosome preparations from large specimens of fishes using in vitro short treatment with colchicine. Experientia 49:810813.

[6] Fujiwara A, Abe S, Yamaha E, Yamazaki F and Yoshida MC (1998) Chromosomal localization and heterochromatin association of ribosomal RNA gene loci and silverstained nucleolar organizer regions in salmonid fishes. Chrom Res 6:463471.

[7] Hatanaka T and Galetti Jr PM (2004) Mapping of the 18S and 5S ribosomal RNA genes in the fish Prochilodus argenteus, Agassiz, 1829 (Characiformes, Prochilodontidae). Genetica 122:239244.

[8] Jesus CM and MoreiraFilho O (2003) Chromosomal location of 5S and 18S rRNA genes in Prochilodus lineatus (Characiformes, Prochilodontidae). Caryologia 56:281287.

[9] Kavalco KF, Pazza R, Bertollo LAC and MoreiraFilho O (2004) Gene mapping of 5S rDNA sites in eight fish species from the Paraíba do Sul river basin, Brazil. Cytogenet Genome Res 106:107110.

[10] Kavalco KF and MoreiraFilho O (2003) Cytogenetical analyses in four species of the genus Astyanax (Pisces, Characidae) from Paraíba do Sul river basin. Caryologia 54:453461.

[11] Levan A, Fredga K and Sandberg AA (1964) Nomenclature for centromeric position on chromosomes. Hereditas 52:201220.

[12] Long EO and David ID (1980) Repeated genes in eukaryotes. Annu Rev Biochem 49:727764.

[13] Mandrioli M, Manicardi GC, Machella N and Caputo V (2001) Molecular and cytogenetic analysis of the goby Gobius niger (Teleostei, Gobiidae). Genetica 110:7378.

[14] Mantovani M, Abel LDS, Mestriner CA and MoreiraFilho O (2004) Evidence of the differentiated structural arrangement of constitutive heterochromatin between two populations of Astyanax scabripinnis (Pisces, Characidae). Genet Mol Biol 27:536542.

[15] Mantovani M, Abel LDS and Moreira Filho O (2005) Conserved 5S and variable 45S rDNA chromosomal localization revealed by FISH in Astyanax scabripinnis (Pisces, Characidae). Genetica 123:211216.

[16] Martins C, Wasko A, Oliveira C and Wright JM (2000) Nucleotide sequence of 5S rDNA and localization of the ribosomal RNA genes to metaphase chromosomes of the tilapiine cichlid fish, Oreochromis niloticus Hereditas 133:3946.

[17] Martins C and Galetti Jr PM (2001) Organization of 5S rDNA in species of the fish Leporinus: Two different genomic locations are characterized by distinct nontranscribed spacers. Genome 44:903910.

[18] Peres WAM (2005) Análise da diversidade cariotípica de Characidae da bacia do São Francisco. Master Thesis, Universidade Federal de São Carlos, São Carlos.

[19] Pinkel D, Straume T and Gray JW (1986) Cytogenetic analysis using quantitative, highsensitivity, fluorescence hybridization. Proc Natl Acad Sci USA 83:29342938.

[20] RoconStange EA and AlmeidaToledo LF (1993) Supernumerary B chromosomes restricted to males in Astyanax scabripinnis (Pisces, Characidae). Brazil J Genet 16:601615.

[21] Schmid M (1980) Chromosome banding in Amphibia: IV. Differentiation of GC and ATrich chromosomes regions in Anura. Chromosoma 77:83103.

[22] Schmid M and Guttenbach M (1988) Evolutionary diversity of reverse (R) fluorescent chromosome bands in vertebrates. Chromosoma 97:101114.

[23] Souza IL, Galián J, De La Rúa P, Bertollo LAC and MoreiraFilho O (2001) Nonrandom distribution of the GCrich heterocromatin and nuclear rDNA sites on Astyanax scabripinnis chromosomes. Cytologia 66:8591.

[24] Williams SM and Strobeck C (1985) Sister chromatid exchange and the evolution of rDNA spacer length. J Theor Biol 116:625636.

Brasil