Genetic consequences of animal translocations: A case study using the field cricket, Gryllus campestris L.

Animal relocations have become a common tool in nature conservation, but the genetic consequences of such projects have rarely been studied in insects. As both natural and artificial formation of new populations may lead to genetic drift (founder effect), decreased genetic diversity and increased rates of inbreeding, genetic analyses can provide valuable information to evaluate the success of a relocation project. The field cricket (Gryllus campestris) has been subjected to reintroduction and translocation projects in England and northern Germany. Here, we present a microsatellite study on the population genetics of one recently established population of this species in comparison with several older populations and some recently colonized sites. Our results show that the translocation did not result in a significant loss of genetic diversity, when compared to source and other natural populations suggesting that translocation of a high number of nymphs from different subpopulations may be a suitable method to decrease the loss of genetic diversity and reduce the risk of inbreeding. Furthermore, the translocation had no negative effect on the source population, which reached a new maximum population size in 2006. An assignment test showed that individuals from the translocated population (F4 generation) were still assigned to the source populations, whereas two young subpopulations that originated by natural colonization from the central population about ten years ago already formed separate genetic clusters. As the strong fragmentation of G. campestris populations in northern Germany hampers natural colonization of newly created potential habitats, translocation projects seem to be an appropriate method to preserve this species.     

Widespread selective sweeps affecting microsatellites in Drosophila populations adapting to captivity: Implications for captive breeding programs

Many threatened species are being maintained in captivity to save them from extinction, often with the eventual aim of reintroduction. The objective of genetic management in captivity is to ‘freeze’ evolution i.e. to avoid genetic adaptation to captivity and to retain genetic diversity. Most current genetic management of threatened species addresses the latter, but does not explicitly address the former. The theory underlying current genetic management and its practical implementation assumes neutrality of loci. However, genetic adaptation in captive populations may cause non-neutral behavior at neutral loci due to selective sweeps (hitchhiking) caused by rapid allele frequency changes at linked fitness loci. We compared changes in microsatellite genetic diversity at eight non-coding loci with neutral predictions in 23 pedigreed captive populations of Drosophila melanogaster maintained with effective sizes of 25 (eight replicates), 50 (6), 100 (4), 250 (3) and 500 (2) for 48 generations. Loss of microsatellite heterozygosity was significantly faster (by 12%) than predicted by neutral theory, as assessed by regressing proportion of heterozygosity retained on pedigree inbreeding coefficients. Further, greater than neutral changes were observed for both variances in allele frequencies across replicates (by 25%), and for temporal changes in allele frequencies (by 33%). All eight microsatellite loci showed signals of selectively-driven changes. Rather than having their evolution ‘frozen’, captive populations are undergoing major genome-wide selective sweeps that affect not only fitness loci but linked neutral loci. Captive genetic management for threatened species destined for reintroduction requires modification to explicitly minimize genetic adaptation to captivity.     

Genetic parameters for large white pigs reared under intensive management systems in Kenya

A lack of performance parameters is one of the factors limiting the implementation of sustainable breeding strategies for the pig industry in Kenya. The objective of this study was to estimate genetic and phenotypic parameters for growth performance of Large White pigs reared under intensive management systems in Kenya. Growth performance data of 1398 pigs with 10 428 records were obtained from the Kenya Agricultural and Livestock Research Organization (KALRO)-Naivasha. Random regression models were used to estimate variance components by fitting different orders of Legendre polynomials. Phenotypic variance increased with age from 3.43±0.28 to 2449.28±392.07, while direct heritability ranged between 0.20±0.04 and 0.52±0.08. Maternal heritability increased from 0.26±0.05 to 0.79±0.04 while permanent environmental heritability was between 0±0.01 and 0.15±0.10. Genetic correlations were greater than 0.48 between all weights and decreased with an increase in age intervals. The first three eigenvalues of the coefficient matrix of the additive genetic covariance accounted for 98.62% of the sum of the eigenvalues. Growth was highly heritable at pre-weaning and influenced by maternal and common environmental effects. The prospect for selection for high sale weights based on pre-weaning growth performance is evident based on the high genetic correlations among body weight measurements.