Mapping of rabbit microsatellite markers using chromosome-specific libraries.

Recently, rabbit microsatellite markers were developed from a chromosome 1-specific library, and seven new markers were incorporated into the genetic map of the rabbit. We have now developed microsatellite markers from chromosomes 3-, 5-, 6-, 7-, 12-, and 19-specific libraries. Linkage analysis was performed with use of these new markers, five recently physically mapped markers (PMP2, TCRB, ALOX15, MT1, and Sol33), microsatellite markers located in the HBA gene cluster, the MHC region and FABP6 gene, and seven biochemical markers (Es-1, Es-3, Est-2, Est-4, Est-6, Est-X, and HP). This analysis enabled us to verify the specificity of the libraries and to determine the position and orientation of the linkage groups on the chromosomes.

Chromosomal localization of genes involved in biosynthesis, metabolism or transport of cholesterol in the rat.

Several genes involved in biosynthesis, transport or metabolism of cholesterol have been localized on rat chromosomes by using a radiation hybrid (RH) panel. The genes, coding for squalene epoxidase (Sqle), mevalonate kinase (Mvk), and farnesyl diphosphate farnesyl transferase 1 (Fdft1) which are involved in cholesterol biosynthesis, have been mapped on chromosome 7, 12, and 15, respectively. The genes coding for phospholipid transfer protein (Pltp), sterol carrier protein-2 (Scp2), ATP binding cassette reporter A7 (Abca7), scavenger receptor class B, type 1 (Cd36l1), steroidogenic acute regulatory protein (Star), and lecithin:cholesterol acyl transferase (Lcat), which are involved in the transfer and/or metabolism of cholesterol, have been mapped on chromosome 3, 5, 7, 12, 16, and 19, respectively. Each of the genes Scp2, Sqle and Fdft1 maps close to a QTL for serum total cholesterol in rat, suggesting that these three genes might represent candidate genes for the previously mapped QTLs.

A rat linkage map based on BC x LEW intercross.

A genetic linkage map consisting of 258 polymorphic loci has been constructed on the basis of an F2 intercross between the BC/CpbU and LEW/OlaHsd inbred rat strains. When compared to previously published maps a discrepancy was found for rat chromosome 7. The map spans a sex-averaged genetic length of 1790 cM and has an average marker spacing of 7.7 cM. It was estimated that this genetic map is linked to about 90% of the DNA in the rat genome. Because LEW/OlaHsd and BC/CpbU strains differ for dietary cholesterol susceptibility and hepatic copper content, the map is considered to be a valuable tool for studying the genetic background of these complex traits.

Mapping of rabbit chromosome 1 markers generated from a microsatellite-enriched chromosome-specific library.

A genomic DNA library was produced from flow-sorted rabbit chromosome 1 and enriched for fragments containing CA-repeats. Clones containing CA-repeats were identified and primers for amplification of the microsatellite were developed after sequencing the clone. The degree of polymorphism was tested in rabbits from different breeds. This approach identified 12 microsatellite markers which could be used for studying linkage relationships in the progeny of an F(2)-intercross: (AX/JUxIIIVO/JU) F(2), and two backcrosses: (OS/JxX/J)X/J and (WH/JxX/J)X/J. Seven of these markers were mapped on chromosome 1.

Mapping of a QTL for serum HDL cholesterol in the rabbit using AFLP technology.

The amplified fragment length polymorphism (AFLP) technique is a DNA technology that generates the so-called AFLP markers. These markers are genomic restriction fragments detected after two rounds of polymerase chain reaction (PCR) without prior knowledge of nucleotide sequence. Here we describe the first application of the AFLP technique in the rabbit. We have tested two primer combinations. The results obtained with the DNA from rabbits of different breeds justify the conclusion that AFLP analysis is an effective tool for genetic studies in the rabbit. In addition, we contribute to the linkage map of the rabbit by localizing two AFLP markers on rabbit linkage group VI (LG VI). For this purpose the progeny of a IIIVO/JU x [IIIVO/JU x AX/JU]F(1) backcross were genotyped for 12 AFLP markers and 3 LG VI classical markers [one coat color marker (e) and two biochemical markers (Es-1 and Est-2)]. AX/JU is a dietary cholesterol-susceptible (hyperresponding) inbred strain and IIIVO/JU is a dietary cholesterol resistant (hyporesponding) inbred strain. Moreover, it is possible to evoke dietary cholesterol-induced aorta atherosclerosis in a relatively short time period in AX/JU rabbits, in contrast to IIIVO/JU rabbits. A significant cosegregation was found between basal serum HDL cholesterol level (i.e., the level on a low-cholesterol, control diet) and an AFLP marker on LG VI. It is concluded that one or more genes of LG VI are regulating the basal serum HDL cholesterol level in rabbits. Thus the present study with rabbits clearly illustrates the value of AFLP markers for the construction of linkage maps and mapping of quantitative trait loci (QTL).

Mapping of microsatellite loci and association of aorta atherosclerosis with LG VI markers in the rabbit.

Twenty-three rabbit microsatellites were extracted from the EMBL nucleotide database. Nine of these markers, together with nine earlier published microsatellite markers, were found to be polymorphic between the AX/JU and IIIVO/JU inbred strains. By using an F(2) intercross we could integrate five markers into the rabbit linkage map. One anonymous microsatellite marker could be assigned to chromosome 1, and one microsatellite marker, located within the metallothionein-1 gene, could be added to linkage group VI (LG VI). Three microsatellite markers (one anonymous, one located within the PMP2 gene, and one located within the FABP6 gene) constitute a new linkage group (LG XI). We also measured the degree of dietary cholesterol-induced aorta atherosclerosis in the F(2) animals. A significant cosegregation was found between the degree of aorta atherosclerosis and the allelic variation of the biochemical marker Est-2 on LG VI in male rabbits. This association was not found in female rabbits.