ABSTRACT
The aim was to establish the genetic diversity and population structure of three guinea pig lines, from seven production zones located in Nariño, southwest Colombia. A total of 384 individuals were genotyped with six microsatellite markers. The measurement of intrapopulation diversity revealed allelic richness ranging from 3.0 to 6.56, and observed heterozygosity (Ho) from 0.33 to 0.60, with a deficit in heterozygous individuals. Although statistically significant (p < 0.05), genetic differentiation between population pairs was found to be low. Genetic distance, as well as clustering of guinea-pig lines and populations, coincided with the historical and geographical distribution of the populations. Likewise, high genetic identity between improved and native lines was established. An analysis of group probabilistic assignment revealed that each line should not be considered as a genetically homogeneous group. The findings corroborate the absorption of native genetic material into the improved line introduced into Colombia from Peru. It is necessary to establish conservation programs for native-line individuals in Nariño, and control genealogical and production records in order to reduce the inbreeding values in the populations.
Subject(s)
Animals , Genetic Variation , Genetics, Population , Guinea Pigs/genetics , Colombia , Conservation of Natural Resources , Microsatellite RepeatsABSTRACT
Population genetics of Colombian Guinea Pigs, Cavia spp. (Rodentia: Caviidae) with RAPD molecular markers. The genus Cavia occurs in South America, mainly in grasslands.. We collected blood samples from 97 individuals in six field populations and analyzed them with RAPD molecular markers. One wild type (C. anolaimae) was differentiated from the domestic form (C. porcellus), in agreement with other authors who used morphological, osteological and karyotipic results. Genetic diversity was considerable in both species, but higher in C. porcellus. The levels of genetic heterogeneity were also higher among the populations of C. porcellus (F ST = 0.254) than among the populations of C. anolaimae (F ST = 0.118). These significant levels of genetic heterogeneity, and the low levels of gene flow, were consistent with a complex domestication process for Cavia porcellus. Rev. Biol. Trop. 56 (3): 1481-1501. Epub 2008 September 30.
En el presente estudio, mostramos los primeros resultados moleculares de formas colombianas de Cavia. Claramente, la población silvestre de C. anolaimae fue genéticamente diferenciada de la forma doméstica, C. porcellus, tal como ha sido demostrado por otros autores utilizando resultados morfométricos, osteológicos y cariotípicos. Ambas especies mostraron un considerable nivel de diversidad genética, aunque el segundo taxon mostró niveles mayores de esta diversidad. Los niveles de heterogeneidad genética también fueron mayores entre las poblaciones de C. porcellus (F ST = 0.254) que entre las poblaciones de C. anolaimae (F ST = 0.118). Esos niveles significativos de heterogeneidad genética, y los consiguientes bajos niveles de flujo génico, fueron discutidos comparativamente con los resultados por otros autores analizando otros marcadores moleculares (citocromo-b mitocondrial). Los resultados aquí mostrados son coherentes con un complejo proceso de domesticación en Cavia porcellus.
Subject(s)
Animals , Genetic Variation , Guinea Pigs/genetics , Colombia , Genetic Markers/genetics , Random Amplified Polymorphic DNA Technique , Species SpecificityABSTRACT
Una manera eficaz de establecer el grado de variabilidad entre y dentro de poblaciones, es a través del análisis de polimorfismos de ADN con marcadores moleculares como los AFLP`s. En este artículo se presenta una metodología que combina la utilización de tarjetas de FTA® (Whatman Bioscience, Cambridge) para colección y conservación de muestras de sangre, con los procedimientos de extracción de ADN y obtención de marcadores AFLP´s, aspectos sobre los cuales no existen antecedentes para la especie Cavia porcellus. Se utilizaron muestras de ADN procedentes de tres poblaciones, dos criollas y una mejorada genéticamente obtenida a partir de un pie de cría procedente del Perú y sometida a selección en Colombia durante varias generaciones. Todos los animales procedieron de la Granja Botana, propiedad de la Universidad de Nariño, Pasto-Colombia. Para la detección de polimorfismos en la longitud de los fragmentos (AFLP`s) se utilizaron uno, tres y cinco discos FTA® de 1.2 mm, cada disco con aproximadamente 25 ng de ADN. Los ensayos indicaron que los mejores productos de amplificación, para la visualización de AFLP´s, se obtuvieron de muestras con tres discos de FTA por individuo, lo que sugiere que con esta metodología,75 ng de ADN por animal son suficientes para detectar polimorfismos de alta calidad en el genoma de Cavia porcellus. Se recomienda el uso de las tarjetas de FTA para el estudio genético de poblaciones de Cavia porcellus, con las modificaciones metodológicas descritas en este artículo para marcadores AFLP´s.
A methodology that includes the use of FTA® (Whatman Bioscience, Cambridge) to collect and store animals` blood samples and the procedures to extract and to get AFLP markers is presented in this paper. A review of the literature indicates that there are no reports concerning both aspects for the Cavia porcellus case. To reach our goal blood samples of three populations Two native ones and other genetically improved- were obtained through heart puncture. This blood was stored in the FTA cards in order to extract, purify, amplify and analyze their DNA forms. All of the animals came from Botana farm of the Universidad de Nariño, located in Pasto, Colombia. For amplifying the AFLP one, three and five 1.2 mm FTA disks of approximately 75 ng of DNA per disk where used. The tests indicated that the best products to amplify and to visualize the AFLP where those ones obtained from samples of three FTA disks per animal. This suggests that 75 ng of DNA per animal is enough to generate AFLP of high quality in the Cavia porcellus` genome. We recommend the use of FTA cards to carry out genetic analyses in the Cavia porcellus, including the methodology modifications presented in this paper.