A paradigm for identification of primary genetic causes of hypertension in rats.

Rapp, John P.

doi:10.1161/01.hyp.5.2_pt_2.i198

Cited by 81 publications

(42 citation statements)

References 25 publications

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“…The presence of the Atp1a1 gene within a QTL where GH alleles are associated with increased blood pressure 12,15 (Figure 2) made it almost mandatory to determine whether the GH rat had the putative A1079T transversion reported by Herrera et al 7,18,25 If the GH rat could be shown to have the transversion, most of the criteria for determining whether this gene is causally involved in hypertension in the GH rat would have been fulfilled. 8 Surprisingly, our results show that neither the GH nor the SS/Jr strain have this transversion.…”

Section: Discussioncontrasting

confidence: 56%

“…2 The reported discovery of an 1079A3 T point mutation in the Atp1a1 allele of the SS/Jr strain 7 presented the possibility of bringing together genetic and physiological findings to explain a component of hypertension in SS/Jr and to fulfill most of the criteria for establishing a gene/causality effect. 8 This mutation would result in a Q276L substitution in the ATPase protein ( Figure 1). Such a substitution was posited to alter the membrane confirmation of Na ϩ ,K ϩ -ATPase, resulting in a change in the Na ϩ -K ϩ pumping ratio and a concordant increase in reabsorption of Na ϩ in the kidney.…”

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confidence: 99%

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Neither the New Zealand Genetically Hypertensive Strain nor Dahl Salt-Sensitive Strain Has an A1079T Transversion in the α1 Isoform of the Na ⁺ ,K ⁺ -ATPase Gene

Barnard

Kelly²,

Manzetti³

et al. 2001

Hypertension

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Abstract-A putative 1079A3 T mutation in the ␣1 isoform of the Na ϩ , K ϩ -ATPase (Atp1a1) gene of the Dahl salt-sensitive rat inbred by John Rapp (SS/Jr) strain was projected to cause a conformation change in the membrane hydrophobic region of the protein product, possibly resulting in hypertension. The existence of the mutation was challenged, but the challenge was apparently rebutted. The New Zealand genetically hypertensive (GH) rat is known to have a blood pressure quantitative trait locus on chromosome 2 containing the gene for the ATPase. Thus, we sought to determine whether the GH rat carried the 1079A3 T transversion. We chose a method, first nucleotide change analysis, that can detect point mutations in a mixed population of polymerase chain reaction (PCR) products, even in the presence of PCR bias, and confirmed our analysis by restriction enzyme digestion of PCR products. To ensure the validity of our analyses, we used site-directed mutagenesis to create positive controls containing the mutation. Surprisingly, we found that neither the GH nor the SS/Jr strain had the A1079T transversion. Indeed, the transversion was not found in any strain tested. As an incidental observation, we have sequenced the intron preceding the exon containing the putative A1079T transversion. Within this intron, a single-base C/T polymorphism was observed at base 132. Our results definitively eliminate the putative A1079T transversion in Atp1a1 as a causative factor underlying hypertension in the GH, spontaneously hypertensive, and SS/Jr rat strains and indicate that alternative candidate genes in the region defined by the chromosome 2 hypertension quantitative trait locus should be examined.

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Section: Discussioncontrasting

confidence: 56%

mentioning

confidence: 99%

Neither the New Zealand Genetically Hypertensive Strain nor Dahl Salt-Sensitive Strain Has an A1079T Transversion in the α1 Isoform of the Na ⁺ ,K ⁺ -ATPase Gene

Barnard

Kelly²,

Manzetti³

et al. 2001

Hypertension

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“…Using a method of continuous backcrossing of sons to the maternal strain allows the replacement of the autosomal background and the X chromosome. 13 Each generation of backcrossing reduces the paternal autosomal component by 50% (Table 1). By generation F 6 , the new backcross substrains have over 99% of the maternal autosomal genes with the paternal Y chromosome (Table 1).…”

Section: Discussionmentioning

confidence: 99%

Separate sex-influenced and genetic components in spontaneously hypertensive rat hypertension.

1991

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“…It has to be kept in mind, however, that the existence of a genetic difference between inbred strains selected for the presence or absence of a particular trait may be the result of either genetic selection for this trait or chance fixation by genetic drift, as indicated above. To distinguish between these two possibilities, a number of criteria have to be met, 14 including demonstration of a Mendelian pattern of inheritance of the marker, the presence of a logical relation between the gene or gene product investigated and cardiovascular regulation, and the continued association of genotype and phenotype in a segregating population. Structural differences of candidate genes between hypertensive and normotensive subjects can be determined using various methods, including direct sequencing or analysis of restriction fragment length polymorphisms (RFLPs).…”

Section: Candidate Genes For Hypertension In Spontaneously Hypertensimentioning

confidence: 99%

Transgenic rats: new animal models in hypertension research. Invited lecture.

et al. 1991

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T he challenge in hypertension research is the elucidation of the primary genetic causes of elevated blood pressure. It is common knowledge that the basic information on how a cell, an organ, and the whole body function resides within the chromosomes and the individual genes, that is, their nucleotide DNA sequence. The problem with understanding primary (genetic) hypertension in humans is that several genes are involved in the cardiovascular control mechanisms and the genetics are complex. In addition, environmental factors that act over extremely long periods of time (such as diets, physical activity, stress) confound the genotype/phenotype relation individually, within a family, and regionally. So although monogenetic, dominant traits and diseases such as some lipid disorders can be studied with relative ease, polygenetic diseases like human primary hypertension remain puzzles for the future, making well-defined experimental models for research mandatory (for review, see References 1-3). In this review we will focus on three different types of experimental hypertension models, each model representing a specific stage of experimental hypertension research.We will discuss the spontaneously hypertensive rat (SHR), first described by Okamoto et al, 4 -5 which was obtained by selective breeding. This rat strain represents, in principle, an experiment of nature. Rats were selected from a normal colony for a specific phenotype, namely, high blood pressure. The hypertension of SHRs clearly is hereditary and genetically determined. These rats, therefore, provide an excellent model for the study of naturally occurring candidate hypertension genes that have accumulated in them. In fact, as will be discussed below, strain- specific structural differences in the renin gene have been found in SHRs.6 A further refinement in the generation of experimental animal models was the introduction by classic breeding of a mutated vasopressin gene into the genetic background of the SHR. Nature provided us with a mutation of interest for hypertension research: the Brattleboro rats, which exhibit a spontaneous point mutation of the vasopressin gene resulting in a shift of the reading frame and production of a nonfunctional, ineffective protein precursor. These animals produce no vasopressin (AVP) and have a hereditary hypothalamic diabetes insipidus (DI). Introduction of this defective gene into SHRs proved conclusively and definitely that AVP is not necessary for the elevation and maintenance of hypertension. The drawback of this approach is the necessity to wait for spontaneous and natural gene mutations before they can be introduced into new rat strains.With the availability of molecular biological approaches, it now is possible to design a more rational animal model. Gene technology makes it possible to introduce new, additional genes in normotensive and hypertensive animals. It also is possible, in the mouse, to delete or mutate specific genes, and similar technology is being developed for use in the rat. This marks the important t...

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A paradigm for identification of primary genetic causes of hypertension in rats.

Cited by 81 publications

References 25 publications

Neither the New Zealand Genetically Hypertensive Strain nor Dahl Salt-Sensitive Strain Has an A1079T Transversion in the α1 Isoform of the Na ⁺ ,K ⁺ -ATPase Gene

Neither the New Zealand Genetically Hypertensive Strain nor Dahl Salt-Sensitive Strain Has an A1079T Transversion in the α1 Isoform of the Na ⁺ ,K ⁺ -ATPase Gene

Separate sex-influenced and genetic components in spontaneously hypertensive rat hypertension.

Transgenic rats: new animal models in hypertension research. Invited lecture.

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A paradigm for identification of primary genetic causes of hypertension in rats.

Cited by 81 publications

References 25 publications

Neither the New Zealand Genetically Hypertensive Strain nor Dahl Salt-Sensitive Strain Has an A1079T Transversion in the α1 Isoform of the Na + ,K + -ATPase Gene

Neither the New Zealand Genetically Hypertensive Strain nor Dahl Salt-Sensitive Strain Has an A1079T Transversion in the α1 Isoform of the Na + ,K + -ATPase Gene

Separate sex-influenced and genetic components in spontaneously hypertensive rat hypertension.

Transgenic rats: new animal models in hypertension research. Invited lecture.

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Neither the New Zealand Genetically Hypertensive Strain nor Dahl Salt-Sensitive Strain Has an A1079T Transversion in the α1 Isoform of the Na ⁺ ,K ⁺ -ATPase Gene

Neither the New Zealand Genetically Hypertensive Strain nor Dahl Salt-Sensitive Strain Has an A1079T Transversion in the α1 Isoform of the Na ⁺ ,K ⁺ -ATPase Gene