Detection of quantitative trait loci for backfat thickness and intramuscular fat content in pigs (Sus scrofa).

In an experimental cross between Meishan and Dutch Large White and Landrace lines, 619 F(2) animals and their parents were typed for molecular markers covering the entire porcine genome. Associations were studied between these markers and two fatness traits: intramuscular fat content and backfat thickness. Association analyses were performed using interval mapping by regression under two genetic models: (1) an outbred line-cross model where the founder lines were assumed to be fixed for different QTL alleles; and (2) a half-sib model where a unique allele substitution effect was fitted within each of the 19 half-sib families. Both approaches revealed for backfat thickness a highly significant QTL on chromosome 7 and suggestive evidence for a QTL at chromosome 2. Furthermore, suggestive QTL affecting backfat thickness were detected on chromosomes 1 and 6 under the line-cross model. For intramuscular fat content the line-cross approach showed suggestive evidence for QTL on chromosomes 2, 4, and 6, whereas the half-sib analysis showed suggestive linkage for chromosomes 4 and 7. The nature of the QTL effects and assumptions underlying both models could explain discrepancies between the findings under the two models. It is concluded that both approaches can complement each other in the analysis of data from outbred line crosses.

Development and mapping of polymorphic microsatellite markers derived from a chicken brain cDNA library.

Until now the genetic linkage map in chicken has ben based mainly on random genomic markers. The addition of expressed sequence tags (ESTs) to the genetic linkage maps is becoming more important because ESTs can form the basis for comparative mapping studies. This may be helpful for the detection of candidate genes for quantitative trait loci (QTLs). In our study we used a (TG)13 repeat as probe for the detection of microsatellites in a chicken brain cDNA library. After hybridization 0.15% of the cDNA clones gave a positive signal. The cDNA complexity of the library was high; of the 90 cDNA clones that were sequenced 60 occurred only once. For 29 clones primer sets for the polymerase chain reaction could be developed. Twenty-one microsatellites were polymorphic on one or more of the test panels and 15 markers could be mapped on either or both of the international reference families. Because sequence homology between chicken and mammalian cDNAs is sometimes low it was difficult to assess the level of sequence homology that indicated a true homologous transcript. In our study seven cDNA cones, of which three could be mapped, showed a relatively high percentage of sequence homology with sequences found in other species. Because sequencing and mapping of expressed sequence tags in human and mouse is progressing very rapidly, it is predicted that further information will soon be readily available. Therefore, increasing the number of expressed sequences on the chicken genetic linkage map will be of value for comparative mapping studies in the near future.

Preliminary linkage map of the chicken (Gallus domesticus) genome based on microsatellite markers: 77 new markers mapped.

Microsatellite polymorphisms are finding increasing use in genetics. The objectives of this study were 1) to enlarge the number of markers to contribute to a well-defined linkage map of the chicken genome; and 2) to create a preliminary linkage map only based on microsatellite markers. The need for microsatellite markers is high for performing a whole genome scan for the identification of quantitative trait loci. Seventy-seven newly developed microsatellite markers that were polymorphic on either one or both of the reference populations were mapped and in combination with all previously described markers, used to construct a preliminary linkage map of the chicken genome. The 128 microsatellite markers mapped thus far cover 23 of the 38 linkage groups of the East Lansing reference population. In the case of the Compton reference population, 20 linkage groups out of 40 are covered with microsatellite markers. No linkage was found in the East Lansing population with five markers, and in the case of the Compton population four markers were unlinked. About 42 and 32% of the East Lansing and Compton maps, respectively, were covered by the 128 microsatellite markers. The microsatellite markers are well dispersed among the various linkage groups and there was no evidence for clustering of the markers within the map. With the 38 markers that were mapped on both reference populations, 10 of the East Lansing linkage groups could be associated with 13 of the Compton linkage groups.