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Cross-species microsatellite amplification in South American Caimans (Caiman spp and Paleosuchus palpebrosus)
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     IUniversidade de So Paulo, Centro de Energia Nuclear na Agricultura, Piracicaba, SP, Brazil

    IIUniversidade de So Paulo, Escola Superior de Agricultura "Luiz de Queiroz", Laboratorio de Biotecnologia, Piracicaba, SP, Brazil

    IIIUniversidade de So Paulo, Escola Superior de Agricultura "Luiz de Queiroz", Laboratorio de Ecologia Animal, Piracicaba, SP, Brazil

    IVCurrent address: Universidade Federal da Bahia, Departamento de Biologia Geral, Laboratorio de Biologia Celular e Molecular, Salvador, Ba, Brazil

    ABSTRACT

    Microsatellite DNA markers have been used to assess genetic diversity and to study ecological behavioral characteristics in animals. Although these markers are powerful tools, their development is labor intensive and costly. Thus, before new markers are developed it is important to prospect the use of markers from related species. In the present study we investigated the possibility of using microsatellite markers developed for Alligator mississipiensis and Caiman latirostris in South American crocodilians. Our results demonstrate the use of microsatellite markers for Paleosuchus palpebrosus, Caiman crocodilus and Caiman yacare.

    Key words: SSR, STR, primers, crocodilians, Alligatorinae.

    Microsatellite DNA markers are simple sequence repeats (Tautz et al., 1986) distributed along the genome (Litt and Luty, 1989) that have been used to assess genetic diversity and to study ecological behavioral characteristics such as mating system and dispersal pattern in reptiles and amphibians (Avise, 1994; Forstner and Forstner, 2002), including the timber rattlesnake Crotalus horridus (Villareal et al., 1995), Alligator mississipiensis (Glenn et al., 1996; Glenn et al., 1998; Davis et al., 2001a), and Crocodylus spp. (Dever et al., 2001; FitzSimmons et al., 2001; Verdade et al., 2002).

    Microsatellite markers are powerful research tools but their development is labor intensive and costly. Consequently, researchers have tried to use microsatellite markers developed for one species in another (Moore et al., 1991). Microsatellite markers developed for Alligator mississipiensis have been successfully used in closely related Alligatorinae species (Glenn et al., 1998); however, transference is more effective at the family or subfamily level (Glenn et al., 1998; Zucoloto, 1998).

    All South American crocodilians (Caiman spp., Melanosuschus niger and Paleosuchus spp.) belong to the Alligatorinae subfamily (King and Burke, 1989). To date the only Alligatorinae species with specific microsatellite markers currently developed are Alligator mississipiensis and Caiman latirostris (Glenn et al., 1998; Zucoloto, 2002). Thus, transference of microsatellite markers to other Alligatorinae species could help conservation programs, genetic diversity studies as well as mating behavior and ecological studies

    The present study tested the ability of microsatellite markers previously developed for Alligator mississipiensis (Glenn et al., 1998) and Caiman latirostris (Zucoloto et al., 2002) to amplify orthologous loci in the related South American Alligatorinae species Caiman crocodilus, Caiman yacare and Paleosuchus palpebrosus.

    The blood samples used in this study were from the Brazilian crocodilians P. palpebrosus, C. yacare and C. crocodiles. Samples were obtained from crocodilians maintained at the Department of Zoology, So Paulo State University, Rio Claro, So Paulo (SP), Brazil (UNESP, Rio Claro, SP) and were stored at the Biotechnology laboratory, ESALQ, University of So Paulo, Piracicaba, SP, Brazil.

    Blood was collected from three C. crocodilus specimens (Cc1, Cc2 and Cc3), three C. yacare specimens (Cy1, Cy2 and Cy3) and two P. palpebrosus specimens (Pp1 and Pp2) by puncturing the dorsal branch of the superior cava vein, which runs along the interior of the vertebral column of large reptiles (Olson, 1975). After collection, blood was mixed with lysis buffer (100 mM Tris-HCl, pH 8.0; 100 mM EDTA, pH 8.0; 0.5% SDS (w/v); 10 mM NaCl) (Hoelzel, 1992). The DNA from these samples was then purified by CTAB and chloroform extraction followed by isopropyl alcohol precipitation (Sambrook et al., 1989).

    The Amiμ8, Amiμ11, Amiμ13 and Amiμ20 markers developed for Alligator mississipiensis (Glenn et al., 1998) and successfully used in Caiman latirostris (Zucoloto, 1998) and the Claμ2, Claμ3, Claμ5, Claμ6, Claμ7, Claμ8, Claμ9, Claμ10 e Claμ12 markers (Table 1) developed for C. latirostris (Zucoloto et al., 2002) were tested. The PCR conditions were: 60 mM Tris-HCl and 25 mM Ammonium sulfate and different concentrations of Mg2+ and pH (Table 1), 0.2 mM each dNTP, 0.4 μM each primer pair, 1U Taq DNA polymerase and 100 ng DNA in a 25 μl reaction. After 3 min at 94 °C, 30 or 35 cycles (depending on the individual microsatellite) were performed for 1 min at 94 °C, 1 min at the annealing temperature specific for each locus (Table 1), 2 min at 72 °C, and a final extension step of 10 min at 72 °C.

    The PCR products were loaded onto 2% agarose gel containing a positive control consisting of the amplification product of the locus analyzed in individuals of C. latirostris under the conditions described in Zucoloto (2002), a negative PCR control, and a fx Hae III DNA size marker to estimate the size of the amplified products. Positive amplifications were loaded in a Megabace 1000 DNA sequencer for genotyping. Allele sizes were obtained using the Genotyper software (GE Healthcare).

    Markers developed for A. mississipiensis (Amiμ8, Amiμ11, Amiμ13 and Amiμ20) presented amplification products and polymorphism for all species tested with the exception of the Amiμ8 marker that showed no amplification for P. palpebrosus. The Claμ2, Claμ3, Claμ5, Claμ6, Claμ7, Claμ8, Claμ9, Claμ10 and Claμ12 markers developed for C. latirostris presented amplification products but the Claμ3 and Claμ12 markers showed nonspecific amplification products for C. latirostris (Claμ3) and Palpebrosus (Claμ12). Several loci were monomorphic in at least one species, while the Claμ12 marker was monomorphic in all the species investigated, although it would be premature to assume that these loci are truly monomorphic for the species investigated because only a small number of specimens were used in our study. An exception is the Claμ12 marker, which showed no polymorphism in C. latirostris even when more than 90 individuals were tested (Zucoloto et al., 2002). An interesting observation was that we found that although Claμ3 gave poor amplification results in C. latirostris it worked well in C. crocodilus, C. yacare and P. palpebrosus.

    Despite some exceptions, allele sizes for C. crocodilus and C. yacare were in agreement with the size range observed for C. latirostris by Zucoloto et al. (2002) (Table 2). The Amiμ8 marker showed no PCR amplification product for P. palpebrosus and allele sizes for C. crocodilus and C. yacare were out of the range of those observed for C. latirostris (Table 2). Amplification for P. palpebrosus diverged from that observed for the other species, as can be observed in Table 2 for the Amiμ13, Amiμ20, Claμ3, Claμ5, Claμ6, Claμ7, Claμ8 and Claμ10 markers.

    The efficiency of heterologous amplification observed in this study was 100% among the caimans and 84.6% between C. latirostris and P. palpebrosus (Table 2). These results were to be expected considering the evolutionary distance between the species (Primmer et al, 1996).

    This study supplied the first set of data showing heterologous amplification of microsatellites for C. crocodilus, C. yacare and P. palpebrosus. Future studies with larger sample sizes are necessary to establish if the markers show Mendelian segregation and determine polymorphism information content (PIC) in the 'caiman complex'. Once these markers are fully characterized they may be able to contribute to the evaluation of genetic diversity, conservation efforts and the elucidation of possible genetic flow between C. crocodilus crocodilus and C. crocodilus yacare.

    Acknowledgments

    We thank Dr. Augusto Shinya Abe (UNESP, Rio Claro) who kindly granted us access to his caiman collection for blood samples. This work was supported by grants from CNPq (grant number 200153/93-5) and FAPESP (grant numbers 00/01495-3 and 99/02605-8).

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