Alain Bataillard

Mapping the Genetic Determinants of Hypertension, Metabolic Diseases, and Related Phenotypes in the Lyon Hypertensive Rat

The complex nature of hypertension makes identifying the pathophysiology and its genetic contributions a challenging task. One powerful approach for the genetic dissection of blood pressure regulation is studying inbred rat models of hypertension, as they provide natural allele variants but reduced heterogeneity (both genetic and etiologic). Furthermore, the detailed physiologic studies to which the rat is amenable allow for the determination of intermediate phenotypes. We have performed a total genome scan in offspring of an F2 intercross between the Lyon hypertensive (LH) and Lyon normotensive rat strains to identify linkage of anthropometric, blood pressure, renal, metabolic, and endocrine phenotypes. Quantitative trait locus (QTL) regions involved in blood pressure regulation, end-stage organ damage, body and organ weight, and lipid metabolism in the LH rat were identified on chromosomes 1, 2, 3, 5, 7, 10, 13, and 17, with 2 phenotypes associated with the metabolic syndrome identified on chromosomes 1 and 17. Regions on chromosomes 2, 13, and 17 were revealed to be important for blood pressure regulation. Regions on chromosome 17 were found to significantly contribute to both metabolic homeostasis and blood pressure regulation; 2 aggregates of a total of 23 QTLs were identified, including several “intermediate phenotypes.” These intermediate phenotypes may be used as closer surrogates to the mechanisms leading to hypertension and metabolic dysfunction in the LH rat.

Effects of chromosome 17 on features of the metabolic syndrome in the Lyon hypertensive rat

The metabolic syndrome (involving obesity, hypertension, dyslipidemia, insulin resistance, and a proinflammatory/prethrombotic state) is a major risk factor for cardiovascular disease. Its incidence continues to rise, in part because of the epidemic increase in obesity. The Lyon hypertensive (LH) rat is a model for hypertension and several other features of the metabolic syndrome, having high body weight, plasma cholesterol, and triglycerides, increased insulin-to-glucose ratio, and salt-sensitive hypertension. Previous genetic studies in LH/Mav rats and a normotensive control (LN/Mav) identified quantitative trait loci (QTLs) on rat chromosome (RNO)17 for multiple features of the metabolic syndrome. To further evaluate the role of RNO17 in the LH rat, we generated a consomic strain (LH-17(BN)) by substituting LH RNO17 with that of the sequenced Brown Norway (BN/NHsdMcwi) rat. Male LH and BN rats and LH-17(BN) rats were characterized for blood pressure and metabolic and morphological parameters. Similar to the protective effect of LN alleles, the LH-17(BN) rat also showed decreased body weight, triglycerides, and blood pressure; however, there was no significant difference in cholesterol or insulin-to-glucose ratio. Therefore, the substitution of the LH chromosome 17 is sufficient to recapitulate some, but not all, of the traits previously mapped to this chromosome. This could be due to the lack of a susceptible LH genome background or due to the introgression of chromosome 17 from another strain. Regardless, this study provides a single-chromosome genetic model for further dissection of blood pressure and morphological and metabolic traits on this chromosome.

Silica attenuates hypertension in Lyon hypertensive rats

Background and objective Evidence has been provided suggesting an association between hypertension and immune dysfunction in Lyon hypertensive (LH) rats. In the present study, we investigated the possible role played by macrophages in LH rats by examining the blood pressure consequences of the chronic administration of silica, a selective toxin to macrophages in vivo. Design and methods LH and Lyon low blood pressure (LL) male rats were treated with silica at a dose of 200 mg/kg per week intraperitoneally from age 4–10 weeks. Controls received saline. Blood pressure was measured by plethysmography from age 6–10 weeks and an intra-arterial recording was performed in 11-week-old, freely moving rats. Results Treatment with silica did not modify blood pressure in LL rats at any age. In contrast, 1 week after the beginning of the treatment, the blood pressure of silica-treated LH rats was lower than that of untreated LH rats. As shown by intra-arterial recording, the effect persisted 1 week after cessation of the treatment. In addition, silica decreased the left ventricle weight in LH but not in LL rats. Conclusion The present results show that weekly administration of silica in young LH rats attenuates the development of hypertension and of left ventricular hypertrophy, a finding which suggests that macrophage-mediated immune reactions may play a pathogenic role in LH rats.

Implication of chromosome 13 on hypertension and associated disorders in Lyon hypertensive rats.

Background Hypertension and associated disorders are major risk factors for cardiovascular disease. The Lyon hypertensive rat (LH) is a genetically hypertensive strain that exhibits spontaneous and salt-sensitive hypertension, exaggerated proteinuria, high body weight, hyperlipidemia, and elevated insulin-to-glucose ratio. Previous genetic mapping identified quantitative trait loci (QTLs) influencing blood pressure (BP) on rat chromosome 13 (RNO13) in several models of hypertension. Methods To study the effects of a single chromosome on the mapped traits, we generated consomic strains by substituting LH RNO13 with that of the normotensive Brown Norway (BN) strain (LH-13BN) and reciprocal consomics by substituting a BN RNO13 with that of LH (BN-13LH). These reciprocal consomic strains, as well as the two parental strains were characterized for BP, metabolic and morphological parameters. Results Compared with LH parents, LH-13BN rats showed decreased mean BP (up to −24 mmHg on 2% NaCl in the drinking water), urine proteins and lipids, and increased body weight. Differences between BN-13LH and BN rats were much smaller than those observed between LH-13BN and LH rats, demonstrating the effects of the highly resistant BN genome background. Plasma renin activity was not affected by the substitution of RNO13, despite the significant BP differences. Conclusion The present work demonstrates that RNO13 is a determinant of BP, proteinuria, and plasma lipids in the LH rat. The distinct phenotypic differences between the consomic LH-13BN and the LH make it a powerful model to determine genes and pathways leading to these risk factors for cardiovascular and renal disease.

Partial transfer of genetic hypertension by lymphoid cells in Lyon rats

Background and objective The involvement of immune factors in a given disease is suggested by evidence that a disease can be prevented by immunosuppression and can be transferred by lymphoid cells. Because the first type of experimental result was achieved in Lyon hypertensive (LH) rats, the present study was undertaken to determine whether hypertension can be transferred to normotensive recipients. As a control, the blood pressure effects of lymphoid cell grafts from renovascular hypertensive donors were also determined. Design and methods Splenocytes and lymph node cells from LH and Lyon low-blood pressure (LL) rats with two-kidney Goldblatt hypertension were respectively injected into LH x Lyon normotensive (LN) F1 hybrids and LL rats aged 7, 8, 9 and 10 weeks. Blood pressure was measured by plethysmography from age 6 to 13 weeks and an intra-arterial recording was performed in 14-week-old conscious rats. Results Lymphoid cell injections from LL rat donors with two-kidney hypertension did not modify the blood pressure of LL rat recipients. In contrast, lymphoid cell grafts from LH rat donors induced a significant increase in blood pressure in F1 recipients compared with control F1 rats after the first injection. As confirmed by intra-arterial recording, this blood pressure effect lasted until age 14 weeks (145 ± 1 versus 137 ± 1 mmHg in grafted and ungrafted F1, respectively). It was not related to alterations in the acute role of the renin-angiotensin and sympathetic nervous systems and was not associated with increased pressor responses to the vasoconstrictor drugs tested. Conclusion The present study demonstrates that genetic hypertension can be partially transferred by lymphoid cells in F1 recipients. The effect seems to be specific to genetic hypertension because lymphoid cells from renovascular hypertensive donors failed to transfer this secondary form of hypertension. The present results support the hypothesis that cellular immune reactions contribute to the pathogenesis of hypertension and LH rats.

Renal circulation in genetic experimental hypertension

This chapter focused on rat models of genetic hypertension since (1) they are widely used and (2) they allow renal function and especially RBF to be measured with a relative accuracy. The various techniques used to obtain RBF (microspheres, pulsed Doppler, ultrasonic transit time, and laser Doppler methods) are presented with their major advantages and limitations. The most frequently used experimental conditions are described since they largely influence the data. Finally, the results obtained in various strains of genetically hypertensive rats are summarized with a special emphasis on the existence of preglomerular vasoconstriction in most of these strains, which makes them close to a “multiple, micro-Goldblatt renal hypertension”.

FETAL LIVER CELL TRANSPLANTATION FAILS TO TRANSFER HYPERTENSION FROM GENETICALLY HYPERTENSIVE RATS TO NORMOTENSIVE RATS OF THE LYON STRAIN

The involvement of an auto-immune mechanism has been suggested in the development and/or the maintenance of hypertension in male, genetically hypertensive rats of the Lyon strain (LH). The aim of this study was to determine whether hypertension may be transferred, by lymphoid cells, from hypertensive donors to male, normotensive rats of the Lyon strain (LN). Experiments designed to induce a resistance to hypertension in LH rats by transfer of lymphoid cells from LN animals were also performed. Since LH and LN are mismatched at the major histocompatibility complex, transfers of fetal liver cells (FLC from fetuses of 13–14 days gestation were performed. These experiments demonstrate the ability of FLC to allow a prolonged survival (over 17 weeks) without graft versus host disease in the rat. As regards the blood pressure level, no LN recipient having received FLC from LH donor became hypertensive, thus showing that hypertension cannot be transferred by lymphoid cells in normotensive animals. Resistance to hypertension was so weakly transferred to hypertensive rats (results being significantly different only at 10 weeks post-grafting) that it may be considered doubtful.