SciELO - Scientific Electronic Library Online

 
vol.20 número2Técnica de marcado por decoloración de pelo en el lobo marino otaria flavescens: descripción y evaluación del métodoThe wild rodent akodon azarae (Cricetidae: Sigmodontinae) as intermediate host of Taenia taeniaeformis (Cestoda: Cyclophyllidea) on poultry farms of central Argentina índice de autoresíndice de materiabúsqueda de artículos
Home Pagelista alfabética de revistas  

Servicios Personalizados

Revista

Articulo

Indicadores

  • No hay articulos citadosCitado por SciELO

Links relacionados

Compartir


Mastozoología neotropical

versión On-line ISSN 1666-0536

Mastozool. neotrop. vol.20 no.2 Mendoza dic. 2013

 

NOTA

Chromosomal differentiation in Kerodon rupestris (rodentia: caviidae) from the brazilian semi-arid region

 

Gisele Lessa1, Margaret M. O. Corrêa2, Leila M. Pessôa2, and Ighor A. Zappes1

1 Museu de Zoologia João Moojen, Universidade Federal de Viçosa, 36570-000 Viçosa, Minas Gerais, Brazil [Correspondence: Gisele Lessa <gislessa@yahoo.com.br>].
2 Departamento de Zoologia, Instituto de Biologia, Universidade Federal do Rio de Janeiro, Rio de Janeiro, RJ, Brazil.

Recibido: 2 octubre 2012.
Aceptado: 15 mayo 2013.
Editor Asociado: UFJ Pardiñas


ABSTRACT.

Kerodon rupestris (Wied, 1820) is the most specialized species among caviid rodents and is endemic to the extensive rocky outcrops in the semi-arid region in Brazil. Herein we describe different karyotypes for K. rupestris, based on samples collected in Itapajé, Ceará (CE), Iraquara in Bahia (BA), and Botumirim in Minas Gerais (MG). Our samples included northern, center and southern populations in the range of the species dis-tribution. The results were compared with a karyotype from Pernambuco previously described for the species. The diploid number (2n = 52) was constant among the analyzed population samples, but the fundamental number (FN) varied from 92 in Itapajé (CE) and Iraquara (BA), to 94 in Botumirim (MG). Pericentric inversions affecting one small pair of acrocentric chromosomes may explain this variation. C-Bands showed that constitutive heterochromatin was distributed in the pericentromeric region of all chromosomes, constant for all examined populations. NOR sites were found in chromosomes pairs 10 and 11, constant for all populations. X chromosome was entirely heterochromatic, with greater heterochromatin concentration in interstitial and distal parts of the arms. Y chromosome was completely heterochromatic. Differences in chromosomal composition in Botumirim sample are congruent with the results of previous studies about cranial variability: Botumirim had the largest cranial size and was discriminated from other population samples in the multivariate character space. Since Botumirim is only 100 Km away from the type locality, it is proposed-in congruence with previously published results-that the FN for the species is polytypic (94/92).

RESUMO.

Diferenciação cromossômica em Kerodon rupestris (Rodentia: Caviidae) da região semiárida brasileira.

Kerodon rupestris (Wied, 1820) é a espécie mais especialista entre os roedores caviídeos endêmica dos afloramentos rochosos da região semiárida do Brasil, a Caatinga. No presente trabalho foram descritos diferentes cariótipos para K. rupestris, baseado em amostras coletadas em Itapajé, Ceará (CE), Iraquara na Bahia (BA) e Botumirim em Minas Gerais (MG). As amostras incluem populações do norte, centro e sul da distribuição da espécie. Os resultados foram comparados com um cariótipo de Pernambuco, previamente descrito para a espécie. O número diploide (2n = 52) foi constante para as populações analisadas, mas o número fundamental (FN) variou de 92 em Itapajé (CE) e Iraquara (BA), para 94 em Botumirim (MG). Inversões pericêntricas afetando um pequeno par de cromossomos acrocêntricos podem explicar essa variação. Bandas C mostraram que a heterocromatina constitutiva estava distribuída na região pericentromérica de todos os cromossomos, constante para todas as amostras estudadas. Sítios de NOR foram encontrados nos pares de cromossomos 10 e 11, também constantes para todas as populações. O cromossomo X é inteiramente heterocromático, com grande concentração de hetero-cromatina nas porções intersticial e distal dos braços. Diferenças na composição cromossômica nas amostras de Botumirim são congruentes com os resultados prévios sobre a variabilidade cranial: os indivíduos de Botumirim apresentaram tamanho cranial maior do que os de outras populações no espaço de caractereres multivariados.
Uma vez que Botumirim está a apenas 100 Km de distância da localidade-tipo, propõe-se -de acordo com os resultados publicados previamente- que o FN para a espécie seja classificado como politípico (94/92).

Key words: C-Bands; Cytogenetics; Kerodon rupestris; NOR.

Palavras-chave: Bandas C; Citogenética; Kerodon rupestris; NOR.


Kerodon rupestris (Wied, 1820) is the most specialized species among caviid rodents and it is considered endemic to the extensive rocky outcrops that occur in the Caatinga semi-arid region in Brazil, from Piauí State to northern Minas Gerais State (Lacher, 1979, 1981; Alho, 1982; Mares and Ojeda, 1982; Oliveira et al., 2003; Lessa and Pessoa, 2005). Despite its wide distribution and habitat specialization, little effort has been made to examine karyological variation in this species (Maia and Hulak, 1978; Maia, 1984).

Maia (1984) analyzed karyological variation in the three genera of Brazilian caviids, Cavia (Pallas, 1766) Galea (Meyen, 1833) and Kerodon (Cuvier, 1825), and showed that 80% of their chromosomal complement was composed of biarmed chromosomes and considerable kar-yological symmetry occurred in the genera. In the same study she gave the diploid and fundamental numbers for K. rupestris from Pernambuco as 2n = 52 and FN = 92. C-band results showed that all constitutive heterochromatin was confined to the X chromosome, differing from the pattern observed in Cavia and Galea. No study focusing on karyological variability in K. rupestris has been published since then.

Lessa et al. (2005), studying morphometric characters in K. rupestris, found a clinal increase in cranial size from north to south. The population from Botumirim was completely discriminated in morphometric multivariate space from the other population in the northeastern part of the species range. These authors also suggested that this cranial variation pattern was associated with the distribution of rocky outcrops. Moojen et al. (1997) suggested this association when describing Kerodon acrobata, a new species within this genus.

Central to the understanding of variability in K. rupestris is the inclusion of samples from throughout its range and from places as near as possible to the type locality of the species. The aim of this study is therefore to describe karyological variation in samples from the northern, central and southern parts of the species range, the last area being within 100 km of the type locality, and to compare it with information previously described for a population sample from Pernambuco. A further objective was then to test whether karyological variation corroborated the found morphometric cranial pattern for the species.

We karyotyped one specimen of K. rupestris collected in Itapajé (CE) (03º41'S - 39º34'W), Ceará State (CE) in November 2003. A second karyotyped sample consisted of two specimens collected in Iraquara (BA), (12o 15'S - 41o36'W), in April 2004. The third sample was composed of six specimens collected in Botumirim (MG) (16º52'S - 43º01'W), between June 2001 and July 2002 (Fig. 1).


Fig. 1. Geographical plot of cytogenetically studied lo-calities of Kerodon rupestris in Brazil: (1) Itapagé, Ceará, 2n = 52 and FN = 92; (2) Iraquara, Bahia, 2n = 52 and FN = 92, and (3) Botumirim, Minas Gerais, 2n = 52 and FN = 94.

The skins and skulls of the karyotyped specimens are deposited in the mammal collection of Museu Nacional (MN) in Rio de Janeiro: one female from Itapajé (CE), (MN 67469); two males from Iraquara (BA), (MN 68092 and MN 68094); two males and two females from Botumirim (MG), (MN 65151, MN 67465, MN 67466, MN 67467).

Cytogenetic analyses were based on mitotic metaphase chromosomes from bone marrow, following Ford and Harmerton (1956) with modifications. Chromosomes were stained with Giemsa and classified following Levan et al. (1964). Metacentric, submetacentric and subtelocentric chromosomes are considered biarmed and acrocentric ones uniarmed. C-bands were showed by techniques described by Sumner (1972).

The karyotype of the northern population specimen from Itapajé (MN 67469), had a diploid number (2n) of 52 and a fundamental number (FN) of 92, and was comprised of 21 pairs of metacentric/submetacentric chromosomes, and four pairs of acrocentrics. The X chromosome is a large metacentric, the largest of the karyotype, and the Y is a medium-sized acrocentric (Fig. 2a). The distribution of constitutive heterochromatin (C-banding) in this specimen showed pericentromeric bands in all autosomes. The X chromosome was entirely heterochromatic (with stronger marks in interstitial regions) whereas the Y chromosome was totally heterochromatic (Fig. 3a).


Fig. 2. Karyotype of Kerodon rupestris: (a) conventional staining of a female (Itapajé, MN 67469; 2n = 52, FN = 92); (b) conventional staining of a male (Iraquara, MN 68094; 2n = 52, FN = 92); (c) conventional staining of a male (MN 65150) and XX (inset) of a female specimen (MN 67466; 2n = 52, FN = 94). Scale = 10 µ.


Fig. 3. C-banding of Kerodon rupestris from Itapajé (a), Iraquara (b), and Botumirim (c); arrows point heterochromatic regions in sexual chromosomes.

The karyotype of specimens from the central population, Iraquara (MN 68092 and MN 68094) and distribution of constitutive heterochromatin (C-banding; Fig. 3b), was identical to that of the Itapajé specimen (Fig. 2b).

The karyotype of specimens from Botumirim (MN 65150, MN 65151, MN 67465, MN 67466, and MN 67467), the southern popula-tion sample, had 2n = 52 and NF = 94, and was comprised of 22 pairs of metacentric/ submetacentric chromosomes, and three pairs of acrocentrics. As in the Itapajé and Iraquara karyotypes, the X chromosome was a large metacentric, the largest of the complement, and Y was a medium-size acrocentric (Fig. 2c). The distribution of constitutive heterochromatin (C-banding) showed pericentromeric bands in all autosomes. The X chromosome was entirely heterochromatic (with stronger marks in interstitial regions) whereas the Y chromosome was totally heterochromatic, as in the other two populations (Fig. 3c). For all populations, NOR sites were found in the short arms of chromosome pairs 10 and 11.

Karyological examination of these specimens and Maia's (1984) results revealed that the karyotype of the southern population (Botumirim) has conspicuous differences when compared with northern and central populations. Diploid and fundamental numbers described here (2n = 52 and FN = 92) for K. rupestris from Itapajé (north) and Iraquara (central) corroborate Maia's (1984) results from the Pernambuco population, although our results for distribution of heterochromatin differ from Maia's. Maia's study revealed that all heterochromatin was confined to the X chromosome in the Pernambuco population; in contrast, in all samples used here the distribution of constitutive heterochro-matin (C-banding) showed pericentromeric bands in all autosomes. The X chromosome was entirely heterochromatic (with stronger marks in interstitial regions) whereas the Y chromosome was totally heterochromatic. In all samples, NOR sites were found in the short arms in metacentric chromosomes 10 and 11. That seems to be constant in all populations of K. rupestris.

Species within Caviinae have a high diploid number (2n = 64) and only three of them differ from this number: Galea musteloides (Meyen, 1833) (2n = 68), K. rupestris (2n = 52) and Ca-via aff. C. magna (Ximénez, 1980) (2n = 62) (George and Weir, 1972; Maia, 1984; Gava et al., 1998). Comparisons and more details in diploid and fundamental numbers are shown in Table 1.

Table 1. Summary of karyotype data of the subfamily Caviinae with data of present study. Acronyms read as follows: 2n = diploid number; FN = fundamental number. Modified from George and Weir (1974), and Kasahara and Yonenaga-Yassuda (1984).

A difference in FN was also observed within K. rupestris: between northern and central population samples (NF = 92) and southern population sample (NF = 94). This difference can be explained by a pericentric inversion in one pair of autosomes. These differences in FN found in other caviomorph rodents have led authors to suggest that a complex of spe-cies may be involved. For example there are a number of taxa within Echimyidae which show this pattern. Species in the genus Trinomys have the same 2n but different FNs (Corrêa et al., 2005). The same occurs within species of Proechimys collected in Brazilian Amazon and Cerrado regions (Weksler et al., 2001) and Isothrix (Vié et al., 1996).

In the case of K. rupestris, the difference in FN found in the southern population sample is congruent to the variability described in cranial morphometric characters for this population (Lessa et al., 2005). These results indicate that southern population sample hasprobably undergone processes of differentiation in relation to the other two populations. Future studies on other kinds of chromosomal banding and on molecular data will elucidate the level of divergence among these populations. It is noteworthy that the southern population sample is only 100 km from the type locality reported by Wied (1820) as Rio Belmonte, on the border between northern Minas Gerais State and southern Bahia State. We suggest that the karyotype of the K. rupestris should be taken to be 2n = 52, FN = 94/92 as this group is located in the type locality region.

Acknowledgments.

The authors would like to thank Danilo Souza, Márcia Gomide, Maria Somália Vianna for support and help in fieldwork in Ceará State, as well as the administration of Centro de Recursos Ambientais in State of Bahia represented by Aloísio Cardoso. To Joelma de Lourdes Silva to the material collected in Botumirim, Minas Gerais State. We thank J. A. Oliveira for permission to study specimens and for their hospitality during the visits in Museu Nacional (UFRJ). C. J. Tribe kindly revised an English version of the manuscript. To professors of Citogenetic Laboratory and Vegetal Microscopy (Universidade Federal de Viçosa) for utilization of equipment and some photography used in this study. Work by the authors has been funded by grants from CAPES, Universidade Federal do Rio de Janeiro, and Fundação de Amparo à Pesquisa do Estado do Rio de Janeiro (FAPERJ-E-26/170.547/99). L. M. Pessôa has been partially supported by a fellowship from Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq- 302058/2004-4). Licenses for collecting were provided by Instituto Brasileiro do Meio Ambiente e dos Recursos Naturais Renováveis (IBAMA).

LITERATURE CITED

1. ALHO CJR. 1982. Brazilian rodents: their habitats and habits. Pp. 143-166, in: Mammalian Biology in South America (MA Mares and HH Genoways, eds.). Pittsburgh, University of Pittburgh.         [ Links ]

2. COHEN MM and L PINSKY. 1966. Autosomal polymor-phism via a translocation in the guinea pig Cavia porcellus. Citogenetics 5:120-122.         [ Links ]

3. CORRÊA MMO, MOG LOPES, EVC CÂMARA, LC OLIVEIRA, and LM PESSÔA. 2005. The karyotypes of Trinomys moojeni (PESSÔA, OLIVEIRA and REIS, 1992) and Trinomys setosus elegans (LUND, 1841) (RODENTIA, ECHIMYIDAE) from Minas Gerais, eastern Brazil. Arquivos do Museu Nacional 63:169-174.         [ Links ]

4. DUNNUM JL and J SALAZAR-BRAVO. 2006. Karyotypes of some members of the genus Cavia (Rodentia: Caviidae) from Bolivia. Journal of Mammalian Biology - Zeitschrift für Saugetierkunde 71:366-370.         [ Links ]

5. FORD CE and JL HARMERTON. 1956. A colchicine hypotonic citrate squash sequence for mammalian chromosomes. Stain Technology 31:247-251.         [ Links ]

6. GAVA A, TRO FREITAS, and J OLIMPIO. 1998. A new karyotype for the genus Cavia from a southern island of Brazil (Rodentia-Caviidae). Genetic Molecular Biology 21:1-7.         [ Links ]

7. GEORGE W and BJ WEIR. 1974. Hystricomorph chromo-somes. Symp. Zoological Society of London 34:79-108.         [ Links ]

8. GEORGE W, BJ WEIR, and J BEDFORD. 1974. Chromo-some studies in some members of the family Caviidae (Mammalia: Rodentia). Journal of Zoology 168:81-89.         [ Links ]

9. HOWELL WM and DA BLACK. 1980. Controlled silver staining of nucleolus organizer regions with a protective colloidal developer: A 1-step method. Experientia 36:1014-1015.         [ Links ]

10. KASAHARA S. 1981. Estudos citogenéticos no roedor Cavia aperea (Família Caviidae). Ciência e Cultura 33:657.         [ Links ]

11. KASAHARA S and Y YONENAGA-YASSUDA. 1984. A progress report of cytogenetic data on Brazilian rodents. Revista Brasileira de Genética 7:509-533.         [ Links ]

12. LACHER TE. 1979. Rates of growth in Kerodon rupestris and an assessment of its potential as a domesticated food source. Papeis Avulsos de Zoologia 33:67-76.         [ Links ]

13. LACHER TE. 1981. The comparative social behavior of Kerodon rupestris and Galea spixii and the evolution of behavior in the Caviidae. Bulletin Carnegie Museum of Natural History 17:1-71.         [ Links ]

14. LESSA G and LM PESSÔA. 2005. Variação ontogenética e sexual em caracteres cranianos de Kerodon rupestris (Wied, 1820) (Rodentia: Caviidae). Arquivos do Museu Nacional 63:599-618.         [ Links ]

15. LESSA G, PR GONÇALVES, and LM PESSÔA. 2005. Variação geográfica em caracteres cranianos quantitativos de Kerodon rupestris (Wied, 1820) (Rodentia: Caviidae). Arquivos do Museu Nacional 63:75-88.         [ Links ]

16. LEVAN A, K FREDGA, and AA SANDEBERG. 1964. Nomenclature for centromeric position on chromosomes. Hereditas 52:201-220.         [ Links ]

17. MAIA V. 1984. Karyotypes of three species of Caviinae (Rodentia, Caviidae). Experientia 40:564-566.         [ Links ]

18. MAIA V and A HULAK. 1978. Estudo cromossômico de duas espécies da família Caviidae (Rodentia). Revista Nordestina de Zoologia 1:119-124.         [ Links ]

19. MARES MA and RA OJEDA. 1982. Patterns of diversity and adaptation in South American hystricognath rodents. Pp. 393-412, In: Mammalian Biology in South America (MA Mares and HH Genoways, eds.). Pittsburgh, University of Pittburgh.         [ Links ]

20. MARIANO JS, I FERRARI, and SA SANTOS. 1983. Estudos citogenéticos em preparações obtidas de cultuta de linfócitos nos gêneros Hydrochoerus e Cavia (Rodentia, Mammalia) Ciência e Cultura 35:656.         [ Links ]

21. MOOJEN J, M LOCKS, and A LANGGUTH. 1997. A new species of Kerodon Cuvier, 1825 from the state of Goiás, Brazil (Mammalia, Rodentia, Caviidae). Boletim do Museu Nacional, Nova Série, Zoologia 377:1-10.         [ Links ]

22. OLIVEIRA JA, PR GONÇALVES and CR BONVICINO. 2003. Mamíferos da Caatinga. Recife Publicação Especial, Recife.         [ Links ]

23. SUMNER AT. 1972. A simple tecnique for demonstrat-ing centromeric heterochromatin. Experimental Cell Research 75:304-306.         [ Links ]

24. VIÉ JC, V VOLOBOUEV, JL PATTON, and L GRANJON. 1996. A new species of Isothrix (Rodentia: Echimyidae) from French Guiana. Mammalia 60:393-406.         [ Links ]

25. WEKSLER M, CR BONVICINO, IB OTAZU, and JS SILVA-JÚNIOR. 2001. Status of Proechimys roberti and P. oris (Rodentia: Echimyidae) from eastern Amazonian and central Brazil. Journal of Mammalogy 82:109-122.         [ Links ]

26. WIED M. 1820. Ueber ein noch unbeschreibenes Säugertier aus der Familie der Nager. Isis von Oken 6:43.         [ Links ]