Physical and genetic mapping of the rainbow trout major histocompatibility regions: evidence for duplication of the class I region.

One of the most unexpected discoveries in MHC genetics came from studies dealing with the teleost MHC. Initially discovered in zebrafish, the MHC class I and II regions of all bony fish are not linked. Previous segregation analysis in trout suggested that the class I and II regions reside on completely different chromosomes. To learn more about MHC genomics in trout, we have isolated BAC clones harboring class Ia and Ib loci, a single BAC clone containing an MH class II gene ( DAB), as well as BAC clones containing the ABCB2 gene. Upon PCR and sequence confirmation, BAC clones were labeled and used as probes for in situ hybridization on rainbow trout metaphase chromosomes for determination of the physical locations of the trout MH regions. Finally, SNPs, RFLPs, and microsatellites found within the BAC clones allowed for these regions to be assigned to specific linkage groups on the OSU x Hotcreek (HC) and OSU x Arlee (ARL) genetic linkage maps. Our data demonstrate that the trout MH regions are located on at least four different chromosomes and the corresponding linkage groups, while also providing direct evidence for the partial duplication of the MH class I region in trout.

Genotypic characterization of an MHC class II locus in lake trout ( Salvelinus namaycush) from Lake Superior by single-stranded conformational polymorphism analysis and reference strand-mediated conformational analysis.

This study compares the genotypic information provided by reference strand-mediated conformational analysis and single-stranded confirmational polymorphism (SSCP) analysis for the major histocompatibility complex (MHC) II locus in lake trout. For this study 80 wild-caught animals from the Apostle Islands of Lake Superior were genotyped using both RSCA and SSCP analysis. Their genotypes were recorded using both methods and compared. The genotypic information provided by the 2 methods was essentially the same although some inconsistencies were observed. Both methods detected approximately 65 genotypes, and both were able to distinguish heterozygous and homozygous animals. The analyses determined that only approximately 20% of alleles were shared between 2 morphologically different populations within the sample set, and identified the dominant alleles. SSCP analysis was quicker, simple, and more robust than RSCA. SSCP analysis using fluorescence technologies could be the method of choice for future genotypic analysis of the MHC II locus in salmonids.