Novel genes as primary triggers for polygenic hypertension.

OBJECTIVES: The discovery of causative genes leading to hypertension in animal models can reveal new mechanistic insights into blood pressure (BP) regulations. Previously, we isolated segments that harbor BP quantitative trait loci (QTLs) on rat chromosome 10 as defined by congenic strains made from crosses of inbred hypertensive Dahl salt-sensitive (DSS) and normotensive Lewis rats. The aim of the current study was to identify hypertension-causing genes for each QTL. METHODS: Molecular analysis was performed. RESULTS: A systematic and comprehensive molecular analysis divulged particular genes that carry nonconserved mutations. Specifically, the proline rich 11 gene is likely responsible for C10QTL5. C10QTL1 is one of five genes, namely Benzodiazepine receptor associated protein 1, Loc689764, myotubularin related protein 4, protein phosphatase 1E, PP2C domain containing and ring finger protein 43. Loc100363423 with no known function is a candidate for C10QTL3. The ATP-binding cassette, subfamily A (ABC1), member 8a gene is probably responsible for C10QTL2. CONCLUSIONS: Primary genes initiating polygenic hypertension are those not known to be involved in BP modulation. Novel pathways towards BP homeostasis appear to underlie the functionality of C10QTL5, C10QTL1 and C10QTL3 and C10QTL2. Moreover, these genes may become innovative targets for the diagnosis and therapeutics of essential hypertension.

α-Kinase 2 is a novel candidate gene for inherited hypertension in Dahl rats.

OBJECTIVES: The interval harboring a quantitative trait locus for blood pressure (BP), C18QTL3, contains ß-2 adrenergic receptor (Adrb2) and neural precursor cell expressed, developmentally downregulated 4-like (Nedd4l) genes. None of the other genes in the C18QTL3-residing interval is known to affect BP. The identification of C18QTL3 might uncover a brand new gene that could prosper into a novel diagnostic and/or therapeutic target for essential hypertension, if neither Adrb2 nor Nedd4l could be upheld as candidate genes. METHODS: Congenic fine resolution was combined with gene analyses. RESULTS: The gene encoding α-kinase 2 (Alpk2) contains a three base-pair deletion and multiple nonconserved mutations in its coding region in Dahl salt-sensitive (DSS) rats. In contrast, the gastrin-releasing peptide gene (Grp) possesses two nonconserved mutations, designated as single nucleotide polymorphisms 1 and 2 (i.e. SNP1 and SNP2), but could not be supported as a candidate gene because the C18S.L14 congenic strain displayed a homozygous DSS genotype at both SNP1 and SNP2. Furthermore, Adrb2 and Nedd4l could not account for the BP-diminishing effect of Lewis alleles in C18S.L14, as their DSS alleles bear functionally identical domains as those of Lewis, and no evidence of differential expression and splicing was evident. No significant nucleotide variations were found in 13 other genes closely linked to Alpk2. CONCLUSION: Alpk2 emerged as a strong candidate gene for C18QTL3. The present study is the first to implicate Alpk2 in the genetics of polygenic hypertension and paves the way for novel gene discovery.

Normotension in Lewis and Dahl salt-resistant rats is governed by different genes.

OBJECTIVES: Inbred rodent models simulating essential hypertension and normotension are useful tools in discovering genes controlling blood pressure (BP) homeostasis. An analysis of a F2 population made from crosses of hypertensive Dahl salt-sensitive (DSS) and normotensive Lewis rats did not detect a BP quantitative trait locus (QTL) on chromosome 7 (Chr 7). However, false negativity could not be excluded. If a BP QTL could be proven to exist, what gene(s) may be responsible for this QTL. METHODS: We first constructed reciprocal congenic strains for a Chr 7 segment and determined functional domains of prominent candidate genes. RESULTS: A congenic strain made in the DSS rat background exhibited a BP effect, indicating that a BP QTL, C7QTL, inhabits Chr 7. Contrarily, a congenic strain constructed in the Lewis rat background did not change BP, demonstrating a dependence of C7QTL on the DSS rats environment. Among the candidate genes, tachykinin 2 (Tac2), neurexophilin 4 (Nxph4) and retinol dehydrogenase 2 (Rdh2) bear nonsynonymous changes comparing DSS and Lewis rats, but are the same comparing DSS and Dahl salt-resistant (DSR) rats. In contrast, the Lewis alleles of 11-beta-hydroxylase (Cyp11b1), aldosterone synthase (Cyp11b2) and Cytochrome P-450 11B3 (Cyp11b3) are identical to those of DSS rats, but different from those of DSR rats. CONCLUSION: Thus, the failure to detect a linkage between a Chr 7 segment and BP in F2(DSS × Lewis) can be attributed to false negativity. Tac2, Nxph4 and Rdh2 are priority candidate genes for C7QTL. Lewis and DSR rats are both normotensive, but their underlying genetic determinants are different.

Strong muscle-specific regulatory cassettes based on multiple copies of the human slow troponin I gene upstream enhancer.

High-level tissue-specific expression of recombinant proteins in muscle is an important issue for several therapeutic applications. To achieve this goal, we generated several constructs containing one to five copies of the upstream enhancer (USE) of 160-bp of the human slow troponin I gene, linked to that gene's minimal promoter. We also tested constructs made with one to four copies of a 100-bp deletion of USE (DeltaUSE) reported to drive pan-muscle-specific expression in transgenic mice. These constructs were evaluated by measuring the activity of the reporter gene beta-galactosidase (beta-gal). In cell culture, these multimerized enhancers retained tissue specificity and their transcriptional strength increased with the number of enhancer copies. In myotube cultures (which still contain nondifferentiated cells), constructs containing four and five USE copies were stronger than the cytomegalovirus (CMV) early enhancer/promoter and slightly weaker than the hybrid CMV enhancer/beta-actin (CB) promoter. Those containing three USE, or four DeltaUSE copies were similar in strength to CMV. After electrotransfer of plasmid DNA into the mouse tibialis anterior muscle, the strengths of the two constructs (USEx3 and DeltaUSEx3) were tested; as measured by beta-gal activity in the total muscle lysate and by the number of transduced fibers, they were similar to CMV and CB. Muscle fiber typing, after electrotransfer of the soleus muscle, showed that DeltaUSEx3 and USEx3 were active in slow and fast fibers. The tissue specificity of these two constructs was also evaluated by hydrodynamic plasmid injection through the tail vein. Although significant beta-gal expression was measured in the liver when CMV was tested, no expression above background level was detected with USEx3 and DeltaUSEx3. The strength, muscle specificity, and small size of these transcriptional elements render them very attractive for gene therapy applications.