Genetic dissection of a blood pressure quantitative trait locus on rat chromosome 1 and gene expression analysis identifies SPON1 as a novel candidate hypertension gene.

A region with a major effect on blood pressure (BP) is located on rat chromosome 1. We have previously isolated this region in reciprocal congenic strains (WKY.SHR-Sa and SHR.WKY-Sa) derived from a cross of the spontaneously hypertensive rat (SHR) with the Wistar-Kyoto rat (WKY) and shown that there are 2 distinct BP quantitative trait loci, BP1 and BP2, in this region. Sisa1, a congenic substrain from the SHR.WKY-Sa animals carrying an introgressed segment of 4.3Mb, contains BP1. Here, we report further dissection of BP1 by the creation of 2 new mutually exclusive congenic substrains (Sisa1a and Sisa1b) and interrogation of candidate genes by expression profiling and targeted transcript sequencing. Only 1 of the substrains (Sisa1a) continued to demonstrate a BP difference but with a reduced introgressed segment of 3Mb. Exonic sequencing of the 20 genes located in the Sisa1a region did not identify any major differences between SHR and WKY. However, microarray expression profiling of whole kidney samples and subsequent quantitative RT-PCR identified a single gene, Spon1 that exhibited significant differential expression between the WKY and SHR genotypes at both 6 and 24 weeks of age. Western blot analysis confirmed an increased level of the Spon1 gene product in SHR kidneys. Spon1 belongs to a family of genes with antiangiogenic properties. These findings justify further investigation of this novel positional candidate gene in BP control in hypertensive rat models and humans.

Iterative in vivo assembly of large and complex transgenes by combining the activities of phiC31 integrase and Cre recombinase.

We have used the phiC31 integrase to introduce large DNA sequences into a vertebrate genome and measure the efficiency of integration of intact DNA as a function of insert size. Inserts of 110 kb and 140 kb in length may be integrated with about 25% and 10% efficiency respectively. In order to overcome the problems of constructing transgenes longer than approximately 150 kb we have established a method that we call; 'Iterative Site Specific Integration' (ISSI). ISSI combines the activities of phiC31 integrase and Cre recombinase to enable the iterative and serial integration of transgenic DNA sequences. In principle the procedure may be repeated an arbitrary number of times and thereby allow the integration of tracts of DNA many hundreds of kilobase pairs long. In practice it may be limited by the time needed to check the accuracy of integration at each step of the procedure. We describe two ISSI experiments, in one of which we have constructed a complex array of vertebrate centromeric sequences of 150 kb in size. The principle that underlies ISSI is applicable to transgenesis in all organisms. ISSI may thus facilitate the reconstitution of biosynthetic pathways encoded by many different genes in transgenic plants, the assembly of large vertebrate loci as transgenes and the synthesis of complete genomes in bacteria.