A Search for Genetic Loci Responsible for Stress-Induced Arterial Hypertension in the ISIAH Rats

Hypertension is a widespread human disease caused by a complex interaction of a series of the genetic factors with both each other and the environmental conditions. In this study we aimed at determining the candidate genetic loci responsible for hypertension in the ISIAH rats and studying the dynamics of the relevant genetic and physiological mechanisms in rat ontogeny. The candidate genetic loci were identified from association of the microsatellite markers linked to these loci with arterial hypertension in rat F₂ hybrids exposed to stress. Two populations of F₂ hybrids of different age (3–4 and 6 months) were obtained by crossing hypertensive ISIAH and normotensive WAG rats. We present the results of cosegregation analysis for the following loci: the gene for the Na⁺, K⁺-ATPase alpha 1 subunit (Atp1a1), the endothelin-2 gene (Edn2), the low affinity nerve growth factor receptor gene (Lngfr), and a region of chromosome 10 marked with the D10Rat58 microsatellile located 3 cM away of the aldolase C gene (AldC). The results obtained allowed us to localize the genes responsible for the stress-induced arterial hypertension in the ISIAH rats to the Atp1a1locus (P < 0.05), chromosome 2 and to the Lngfr gene locus (P < 0.05), chromosome 10. The association of hypertensive status with the Lngfr gene was found only in young ISIAH rats whereas in adult rats of this strain, hypertension was associated with the Atp1a1locus.     

Genetic loci for spleen weight and blood pressure in ISIAH rats with inherited stress-induced arterial hypertension

Recently, the important role of the spleen’s function in hypertension development was demonstrated. In this study, the genetic control of absolute and relative spleen weight was investigated to reveal the genetic loci common for spleen traits and for arterial blood pressure at rest and under the emotional stress conditions in ISIAH rats with inherited stress-induced arterial hypertension. The search for genetic loci for absolute and relative spleen weight was performed on 6-month-old F₂ (ISIAH × WAG) hybrid males derived from a cross of hypertensive ISIAH and normotensive WAG rats. One significant QTL mapped on chromosome 1 and 5 suggestive loci were found for relative spleen weight. Four suggestive loci were detected for absolute spleen weight. All detected loci were novel. The significant QTL on chromosome 1 was common for relative spleen weight and arterial blood pressure at rest and under the emotional stress conditions in ISIAH rats. The results suggest that the manifestation of the stress-sensitive arterial hypertension in ISIAH rats may be related to the changes in genetic control of the spleen function.     

Genetic correlation between the arterial pressure response during emotional stress and the alpha1-adrenoreceptor concentration in brain regions]

Arterial blood pressure reactivity to the emotional stress and brain alpha 1-adrenoreceptors concentrations were studied in hypertensive (ISIAH strain) and normotensive (Wistar strain) rats and their F1 and F2 hybrids. Significant correlations between the stress-induced increase in the arterial blood pressure and the amount of alpha 1-adrenoreceptors in hypothalamus (+0.46) and medulla (+0.38) were found in the F2. This cosegregation may point to the significant role of genetically determined peculiarities of expression of alpha 1-adrenoreceptors in brain regions during pathogenesis of arterial hypertension in the ISIAH strain.     

Alpha1 Na,K-ATPase and Na,K,2Cl-cotransporte/D3mit3 loci interact to increase susceptibility to salt-sensitive hypertension in Dahl S(HSD) rats

BACKGROUND: Essential (multigenic) hypertension is a complex multifactorial disease whose genetic etiology has not been unraveled on a major locus-effect investigative paradigm. As with other complex genetic diseases, applying an interacting loci paradigm could be critical in the elucidation of genetic determinants. Having defined the alpha1 Na,K-ATPase (alpha1NK) as a hypertension susceptibility gene in Dahl salt-sensitive (Dahl S) rats, we determined whether alphaINK interacts with another renal epithelial Na transporter to increase susceptibility to salt-sensitive hypertension. We focused on alpha1NK and Na,K,2Cl-cotransporter (NKC) as an a priori candidate interacting gene pair because they comprise a functionally linked Na transport system in renal thick ascending limb of Henle (TALH) epithelial cells and exhibit altered function in prehypertensive Dahl S rats in contrast to Dahl salt-resistant normotensive (Dahl R) rats. MATERIAL AND METHOD: Cosegregation analysis of alphaNK and NKC loci was done in a (Dahl S x Dahl R) F2 cohort characterized for blood pressure by radiotelemetry using the D2mghII microsatellite marker in the alpha1NK gene and the D3mit3 microsatellite marker close to the NKC gene (NKC/D3mit3 locus). Single locus and digenic analyses were performed to establish the individual and interactive genetic contribution to salt-sensitive hypertension. Molecular analysis was then done to support the NKC gene as the likely candidate gene interacting with alpha1NK in Dahl salt-sensitive hypertension pathogenesis. RESULTS: Compared with respective single locus analysis, digenic analysis of 96 F2 (Dahl S x Dahl R) hybrid male rats revealed cosegregation of alpha1NK and NKC/D3mit3 loci as interacting pair with salt-sensitive hypertension with markedly increased significance for systolic (one-way ANOVA p = 10(-6)), diastolic (p = 10(-5)), and mean arterial (p = 10(-6)) blood pressures. Concordantly, two-way ANOVA detected interaction between alpha1NK and NKC loci in determining the levels of systolic (p = 0.004), diastolic (p = 0.008), and mean arterial (p = 0.006) pressures. To unravel potential NKC molecular dysfunction(s) involved in hypertension pathogenesis, we investigated putative differences between Dahl S and Dahl R rats in nucleotide sequence and isoform gene expression of the renal-specific Na,K,2Cl-cotransporter. Molecular analysis revealed an inversion of alternatively spliced NKC-isoform ratios (4B:4A:4F) between Dahl S and Dahl R prehypertensive kidneys supported by four mutations in intron-3 immediately upstream to alternatively spliced exons 4B, 4A, and 4F. No nucleotide changes were detected within the aminoacid encoding exons of NKC. CONCLUSIONS: Altogether, these current data and previous characterization of the role of the Q276L alpha1NK molecular variant in Dahl S hypertension provide cumulative compelling evidence that alpha1NK and NKC/D3mit3 loci interact to increase susceptibility to hypertension in Dahl S rats and that NKC is the likely candidate gene that interacts with alpha 1NK. More importantly, the data substantiate gene interaction as an operative mechanism in multigenic hypertension.     

Hypotensive effect associated with a phospholipase C-delta 1 gene mutation in the spontaneously hypertensive rat.

To identify the genes responsible for blood pressure in the spontaneously hypertensive rat strain, we performed a cosegregation analysis between the genotype and blood pressure in a set of male F2 rats obtained by crossmating SHR with Wistar-Kyoto rats, a parental normotensive strain. Our investigation revealed that the phospholipase C-delta 1 polymorphism, which resulted in missense mutation, cosegregates with the lower blood pressure in SHR, and that PLC-delta 1 gene is located on chromosome 8. On the other hand, we found the lack of cosegregation between blood pressure and the nerve growth factor receptor gene, which is linked to a hypertensinogenic gene locus (denoted as BP/SP-1) on chromosome 10. We propose that PLC-delta 1 gene itself of closely linked gene on chromosome 8 is a new candidate with the hypotensive effect, and that BP-SP1 locus does not directly contribute to blood pressure elevation in original SHR.     

The ISIAH rat locomotion in the open field test is under control of the genes on chromosome 2 and chromosome 16

The QTL analysis was performed in order to identify the genetic loci that contribute to the behavior in the open field tests in the ISIAH rat strain with inherited stress-induced arterial hypertension. Two F2 populations of 3-4-month-old (n = 106) and 6-month-old (n = 130) male rats derived from a cross between the normotensive Wistar albino Glaxo (WAG) and hypertensive ISIAH rats were used in the search for the QTL. In 3-4-month-old rats, QTL were found: a) for the rat locomotion at the periphery of the open field in the region of D2Rat157-D2Rat88 markers (logarithm of odds (LOD) score 4.83; p= 0.000058) on Chr. 2 and in the vicinity of the D16Rat32 marker (LOD score 3.71; p = 0.00023) on Chr. 16. These two QTL describe the 42.9% of the trait variability. b) for the rat locomotion during the first minute of the open field test on Chr.16 near the D16Rat58 marker (LOD score 3.78; p = 0.00028). The results provided support for the existence of the age-dependent differences in the genetic control of the traits analyzed.     

Features of the behavior of the rat with hereditarily determined arterial hypertension

The behaviour of spontaneously hypertensive rats (SHR strain), rats with inherited stress induced arterial hypertension (ISIAH, a new developed strain), and of their normotensive Wistar progenitors was studied. The open-field arena and a device for measuring the total activity in the home cage were used in the behavioural studies. The SHR were much more active in the open--field and home cage tests than the Wistar and ISIAH rats. The basal locomotor activity of the ISIAH strain was lower than that of the Wistar rats, but the ISIAH strain had an index of behavioural reactivity 2.7 fold higher than the Wistar or SHR strains. These behavioural characteristics corresponded to the hypertension patterns of the strains compared. Enhanced spontaneous locomotion of the SHR rats was associated with spontaneous increase in arterial blood pressure. The ISIAH rats showed low spontaneous locomotor activity, but high behavioural and blood pressure reactivity under conditions of mild emotional stress.     

Genetic mapping of a gene causing hypertension in the stroke-prone spontaneously hypertensive rat.

The stroke-prone spontaneously hypertensive rat (SHRSP) is a well-characterized model for primary hypertension in humans. High blood pressure in SHRSP shows polygenic inheritance, but none of the loci responsible have previously been identified. To locate genes controlling this quantitative trait, we mapped a large collection of DNA polymorphisms in a cross between SHRSP and the normotensive WKY strain. Here we report strong genetic evidence that a gene, Bp1, having a major effect on blood pressure maps to rat chromosome 10 with a LOD score of 5.10 and is closely linked to the rat gene encoding angiotensin-converting enzyme (ACE), an enzyme that plays a major role in blood pressure homeostasis and is an important target of anti-hypertensive drugs. We also find significant, albeit weaker, linkage to a locus, Bp2, on chromosome 18. We discuss the implications of genetic dissection of quantitative disease-related phenotypes in mammals.     

Expression of the renin angiotensin system genes in the kidney and heart of ISIAH hypertensive rats

The content of mRNA of renin-angiotensin system (RAS) genes was measured in the kidney and heart of hypertensive ISIAH and normotensive WAG rats using the real-time PCR. A statistically significant decrease in the mRNA level of RAS genes was registered in the kidney of ISIAH rats, including Ren (by 45%), Ace (43%), AT1A (34%), COX-2 (50%). The level of myocardial expression of AT1A decreased by 28% while Ace expression increased by 80%. These results suggest reduction of renal RAS basal activity in the hypertensive ISIAH rats, and therefore this strain of rats may be referred to the group of models of low-renin hypertension. The ISIAH rats were also characterized by a two-fold increase in the connective tissue sodium concentration and also by a small (but statistically significant) increase in plasma sodium concentration (139 ± 0.3 mmol/l versus 136 ± 0.25 mmol/l in WAG rats). These results together with a tendency to a decrease of plasma aldosterone level also support existence of a classical low-renin hypertension in the ISIAH rats. It is suggested that altered function of renal ion channels represents a basis for the development of low renin hypertension in the ISIAH rats. In addition, impairments in renal system of NO synthesis may also contribute to the pathogenesis of arterial hypertension in the ISIAH rats.     

Genetic mapping of quantitative trait loci influencing left ventricular mass in rats

High blood pressure is the leading cause of left ventricular hypertrophy (LVH); however, not all hypertensive patients develop LVH. Genetic factors are important in the development of LVH. With the use of F2 male rats from spontaneously hypertensive rats and Lewis rats, we performed a study to identify the quantitative trait loci (QTL) that influence left ventricular mass (LVM). Mean arterial pressure (MAP) was measured by the direct intra-arterial method in conscious animals, and LVM was determined at 24 wk of age. QTL analysis was done using 160 microsatellite markers for a genome-wide scan. Two loci that influenced body weight-adjusted LVM with logarithm of the odds scores >3.4 were found. One locus on chromosome 17 influenced LVM independently of MAP. Another locus on chromosome 7 influenced LVM and MAP. These findings indicate not only the existence of a gene on chromosome 7 that influences LVM in a manner dependent on blood pressure but also the existence of a gene on chromosome 17 that influences LVM independently of blood pressure.     

Identification of genomic locus responsible for experimentally induced testicular teratoma 1 (ett1) on mouse Chr 18

Spontaneous testicular teratomas (STTs) composed by various kinds of tissues are derived from primordial germ cells (PGCs) in the fetal testes of the mouse. In contrast, intra-testicular grafts of the mouse strain (129/Sv-Ter (+/+)) fetal testes possessed the ability to develop the experimental testicular teratomas (ETTs), indistinguishable from the STTs at a morphological level. In this study, linkage analysis was performed for exploration of possible candidate genes involving in ETT development using F2 intercross fetuses derived from [LTXBJ × 129/Sv-Ter (+/+)] F1 hybrids. Linkage analysis with selected simple sequence length polymorphisms along chromosomes 18 and 19, which have been expected to contain ETT-susceptibility loci, demonstrated that a novel recessive candidate gene responsible for ETT development is located in 1.1 Mb region between the SSLP markers D18Mit81 and D18Mit184 on chromosome 18 in the 129/Sv-Ter (+/+) genetic background. Since this locus is different from the previously known loci (including Ter, pgct1, and Tgct1) for STT development, we named this novel gene “experimental testicular teratoma 1 (ett1)”. To resolve the location of ett1 independently from other susceptibility loci, ett1 loci was introduced in a congenic strain in which the distal segment of chromosome 18 in LTXBJ strain mice had been replaced by a 1.99 Mbp genomic segment of the 129/Sv-Ter (+/+) mice. Congenic males homozygous for the ett1 loci were confirmed to have the ability to form ETTs, indicating that this locus contain the gene responsible for ETTs. We listed candidate genes included in this region, and discussed about their possible involvement in induction of ETTs.     

Manifestation of oxidative stress in the pathogenesis of arterial hypertension in ISIAH rats.

The ISIAH rat strain with stress-sensitive arterial hypertension was intentionally selected to study the role of stress as a factor in the development of arterial hypertension. This study aimed to determine the role of reactive oxygen and nitrogen species (ROS and RNS) in the pathogenesis of hypertension in ISIAH rats. The nitric oxide concentrations measured by EPR were found to be significantly higher for hypertensive ISIAH rats compared with that for normotensive Wistar rats in both the aortic wall (2 times) and cerebellum (1.5 times). The activity of superoxide dismutase measured in the blood of ISIAH rats was found to be about 1.5 times lower compared with that of Wistar rats. These data support the suggestion that ROS and RNS, including superoxide radicals and nitric oxide, may play an important role in development of stress-induced hypertension in ISIAH rats. The tissue content of reduced thiols has been considered as a marker of oxidative damage. To study the tissue oxidative status we used an EPR method for quantitative determination of SH groups. The concentration of reduced thiols in the blood of ISIAH rats was much lower than that in Wistar rats (0.6 +/- 0.05 and 1.57 +/- 0.1 mM, respectively).     

Expression of the pro-opiomelanocortin gene in rats with inherited arterial hypertension]

Expression of pro-opiomelanocortin (POMC) gene in pituitary of rats from newly developed hypertensive strain (ISIAH strain) was studied by dot hybridization. The pUC8 plasmid containing 900 base pair (bp) segment or the human POMC gene corresponding to the major portion of the 3'-nontranslated mRNA region and 60 bp coding for the signal peptide, was used as a probe for hybridization. It was found that the expression of the POMC in pituitary of the hypertensive JSJAH rats was more than 3-fold gene lower as compared to normotensive Wistar strain. The latter is the original strain from which the ISIAH rats were bred. The mechanism of this phenomenon and its possible relation to the arterial hypertension are discussed.     

Comparative analysis of conditioned passive avoidance retention in rats with different forms of inherited arterial hypertension

Comparing behavioral traits of anxiety in elevated plus-maze and retention of passive avoidance response in two rat strains with hereditary arterial hypertension ISIAH (inherited stress induced arterial hypertension) and SHR (spontaneously hypertensive rats) has shown the following. The SHR rats demonstrate impairment in retrieval of passive avoidance, hyperactivity and low anxiety. ISIAH rats showned better avoidance performance, average level of anxiety and activity. The interdependence of two pathologies: hypertension and memory impairment is discussed.     

Analysis of polymorphic DNA markers cosegregation with arterial blood pressure in ISIAH hypertensive rats]

A search for DNA markers of hereditary arterial hypertension in ISIAH rats was performed by means of contemporary molecular genetic approaches. The backcross rat population used for the analyses was derived from a cross of the Wistar x ISIAH F1 progeny with the Wistar rats. Hybridization of the HaeIII-digested DNA samples with the (CAC)5 microsatellite probe revealed cosegregation of the basal arterial pressure value with the 4.8-kb polymorphic DNA fragment. Examination of the DNA polymorphism by means of polymerase chain reaction with arbitrary primers showed an association of the 700-bp polymorphic DNA fragment with the increase of arterial blood pressure under conditions of emotional stress.     

Genetic analysis of some behavioral and physiologic characters in hybrids between hypertensive and normotensive rats. Analysis of the nature of the inheritance]

As a result of crosses between the SHR rats (spontaneously hypertensive strain) and WKY rats (normotensive strain), the F1 and F2 hybrids and the B1 and B2 backcrosses were obtained. Analysis of genetic control nature in these generations revealed that the WKY genes responsible for the level of arterial pressure, sensitivity to the electric current stimulation and salt (sodium and potassium) appetite characteristics were dominant. The heterosis effect was found for the body mass. Analysis of dynamics of different types of exploratory activity (in a shuttle box, in "horizontal plane", in an open field) demonstrated specificity of their genetic formulae and peculiarities of changes in their genetic control during the test.     

Wild rats (Rattus norvegicus) for mapping of disease-resistant genes

Wild rat representing a disease-resistant phenotype and genotype, was used in a crossing study with spontaneously hypertensive rat (SHR) to search for quantitative trait loci (QTL) affecting blood pressure. Therefore, one male wild rat was crossed with SHR females and F1 hybrids were transferred in a pathogen free environment by wet-hysterectomy and backcrossed onto hypertensive SHR rats resulting in first backcross hybrids (BC1). Considering that the F1 hybrids are not uniform, as are the cross hybrids of inbred rat strains, we selected 72 BC1 progeny of one F1 female, which were characterised for systolic blood pressure, measured by tail cuff method and were genetically analysed using 200 microsatellites covering the whole genome. We found suggestive linkage of blood pressure to region on chromosome 2 flanked by D2Mit8 and Fgg loci (lod score 2.3). In addition, possible interaction between genes on chromosomes 7 and 3, X and 3, 14 and 3, 13 and 11 was described, indicating that blood pressure development in the SHR might be the result of interacting genes.     

High blood pressure: hunting the genes.

High blood pressure is a disease of unknown cause. Family history of the disease indicates higher risk, but it is not known which genes are involved or how they interact with environmental influences to produce the disorder. Molecular biology offers an approach to problems that have not so far been solved by classical physiology or biochemistry. By analysing polymorphic variation in chromosome markers such as minisatellite sequences, or by restriction fragment polymorphism analysis of candidate genes, attempts are being made to link genetic variations with hypertension. In genetically hypertensive rats, hypertension is associated with a polymorphism of the renin gene and with other loci on chromosomes 10 and 18. The role of these loci in human hypertension remains to be determined. Other genes such as sodium-lithium countertransport may be involved. Environmental factors such as stress or salt intake could influence the rate or timing of expression of certain genes and thus result in hypertension.     

Two major interacting chromosome loci control disease susceptibility in murine model of spondyloarthropathy

Autoimmune spondylitis was induced in BALB/c mice and their MHC-matched (BALB/c x DBA/2)F1 and F2 hybrids by systemic immunization with cartilage/intervertebral disk proteoglycan (PG). As in human ankylosing spondylitis, the MHC was the major permissive genetic locus in murine PG-induced spondylitis (PGIS). Two major non-MHC chromosome loci with highly significant linkage were found on chromosomes 2 (Pgis2) and 18 (Pgis1) accounting for 40% of the entire F2 trait variance. The dominant spondylitis-susceptibility allele for Pgis2 locus is derived from the BALB/c strain, whereas the Pgis1 recessive allele was present in the disease-resistant DBA/2 strain. The Pgis1 locus significantly affected the disease-controlling Pgis2 locus, inducing as high incidence of spondylitis in F2 hybrids as was found in the spondylitis-susceptible parent BALB/c strain. Additional disease-controlling loci with suggestive linkage were mapped to the chromosomes 12, 15, and 19. Severity of spondylitis in F2 mice positively correlated with serum levels of amyloid A, IL-6, and Pg-specific Abs, and showed negative correlation with Ag-induced T cell proliferation, IFN-gamma, IL-4, and TNF-alpha production. A major locus controlling serum IL-6 was found on chromosome 14 near osteoclast differentiation factor Tnfsf11. Locus on chromosome 11 near the Stat3 and Stat5 genes controlled serum level of the Ig IgG2a isotype. The two major genetic loci Pgis1 and Pgis2 of murine spondylitis were homologous to chromosome regions in human genome, which control ankylosing spondylitis in human patients. Thus, this animal model of experimentally induced spondylitis might facilitate the identification of spondylitis-susceptibility genes in humans.