Richard P. Lifton

Molecular basis of human hypertension: Role of angiotensinogen

Essential hypertension is a common human disease believed to result from the interplay of multiple genetic and environmental determinants. In genetic studies of two large panels of hypertensive sibships from widely separated geographical areas, we obtained evidence of genetic linkage between the angiotensinogen gene (AGT) and hypertension, demonstrated association of AGT molecular variants with the disease, and found significant differences in plasma concentrations of angiotensinogen among hypertensive subjects with different AGT genotypes. The corroboration and replication afforded by these results support the interpretation that molecular variants of AGT constitute inherited predispositions to essential hypertension in humans.

Exclusion of the Na(+)-H+ antiporter as a candidate gene in human essential hypertension.

The primary abnormalities that contribute to the pathogenesis of human essential hypertension are unknown. The known genetic contribution to this disorder suggests the possible use of genetic linkage analysis to test whether specific candidate genes contribute to the pathogenesis of either essential hypertension or intermediate phenotypes. Among such phenotypes, elevated erythrocyte Na(+)-Li+ countertransport (SLC) is the best known, supporting major gene inheritance by pedigree analysis. Striking similarities between SLC and Na(+)-H+ exchange suggest that mutations at the Na(+)-H+ antiporter gene locus (APNH) might result in elevated SLC and contribute to the subsequent pathogenesis of hypertension. We have tested these hypotheses by genetic linkage analysis, with APNH as a candidate gene. By determining genotypes at APNH and flanking loci in pedigrees that support major gene segregation of elevated SLC, we have excluded linkage of APNH and the major SLC locus with a LOD score of -5.91, an odds ratio of almost 1,000,000:1 against linkage. In the analysis of 93 hypertensive sibling pairs, we have further demonstrated that APNH explains none of the variance in SLC in hypertensive individuals (r2 = 6 x 10(-7), p greater than 0.99). Finally, we have directly tested for linkage of APNH to genes predisposing toward hypertension by linkage in hypertensive sibling pairs. Mean allele sharing at APNH is not greater than expected from random assortment in hypertensive siblings (0.92 versus 1.0, p greater than 0.80), and the upper 95% confidence limit of this value (1.04) indicates that mutations at APNH rarely if ever contribute to the pathogenesis of hypertension in this population.(ABSTRACT TRUNCATED AT 250 WORDS)

Non-modulation as an intermediate phenotype in essential hypertension.

Non-modulation is a trait characterized by abnormal angiotensin-mediated control of aldosterone release and the renal blood supply. To determine whether non-modulation defines a specific subgroup of the hypertensive population and its utility as an intermediate phenotype, we have studied the distribution of this quantitative trait, whether its features are reproducible on repeated testing, and whether there is concordance of its multiple features. Essential hypertensive patients (224) and normotensive subjects (119) received an infusion of angiotensin II (Ang II) at 3 ng.kg-1.min-1 for 30-45 minutes. p-Aminohippurate (PAH) clearance was assessed as an index of renal plasma flow while the subjects were on a 200 meq sodium diet; plasma aldosterone levels were measured while the subjects were on a 10 meq sodium diet. In 54 subjects, diuretic-induced volume depletion superimposed on a low salt diet was substituted for the Ang II infusion. The results of each study were submitted to maximum likelihood analysis to assess bimodality. In response to both diuretic-induced volume depletion (p < 0.000023) and Ang II infusion (p < 0.0009), aldosterone responses were bimodally distributed in the essential hypertensive but not in the normotensive subjects, suggesting that this trait identifies a discrete subgroup. In the 59 subjects who had both an adrenal and renal study, 50 (85%) were concordant. Finally, in 27 subjects studied two to six times over a span of 1-60 months, the intraclass correlations of the adrenal, PAH, or both responses were highly significant (p values between 0.001 and 0.00007), indicating high reproducibility of results on repeated testing.(ABSTRACT TRUNCATED AT 250 WORDS)

KANK deficiency leads to podocyte dysfunction and nephrotic syndrome

Steroid-resistant nephrotic syndrome (SRNS) is a frequent cause of progressive renal function decline and affects millions of people. In a recent study, 30% of SRNS cases evaluated were the result of monogenic mutations in 1 of 27 different genes. Here, using homozygosity mapping and whole-exome sequencing, we identified recessive mutations in kidney ankyrin repeat-containing protein 1 (KANK1), KANK2, and KANK4 in individuals with nephrotic syndrome. In an independent functional genetic screen of Drosophila cardiac nephrocytes, which are equivalents of mammalian podocytes, we determined that the Drosophila KANK homolog (dKank) is essential for nephrocyte function. RNAi-mediated knockdown of dKank in nephrocytes disrupted slit diaphragm filtration structures and lacuna channel structures. In rats, KANK1, KANK2, and KANK4 all localized to podocytes in glomeruli, and KANK1 partially colocalized with synaptopodin. Knockdown of kank2 in zebrafish recapitulated a nephrotic syndrome phenotype, resulting in proteinuria and podocyte foot process effacement. In rat glomeruli and cultured human podocytes, KANK2 interacted with ARHGDIA, a known regulator of RHO GTPases in podocytes that is dysfunctional in some types of nephrotic syndrome. Knockdown of KANK2 in cultured podocytes increased active GTP-bound RHOA and decreased migration. Together, these data suggest that KANK family genes play evolutionarily conserved roles in podocyte function, likely through regulating RHO GTPase signaling.

Evidence for heritability of non-modulating essential hypertension.

We have previously described a subset of subjects with essential hypertension who fail to appropriately modulate renal vascular and adrenal reactivity with changes in dietary sodium and in response to infused angiotensin II (Ang II). In this paper, we studied these responses in 13 unselected hypertensive subjects in whom the family history of hypertension had been carefully detailed. Nine of these 13 subjects had a positive family history (FH+) for hypertension and had significantly smaller decrements in renal blood flow with Ang II infusion than the four subjects who had a negative family history (FH−) (−84±16 ml/min/1.73 m+ for FH+ vs. −149 ml/min/1.73 m2 for FH−, p = 0.024). These FH+ subjects also showed smaller increases in renal blood flow with increases in dietary sodium than FH− subjects (7±10 ml/min/1.73 m2 vs. 72±-24 ml/min/1.73 m+, respectively; p = 0.014). When classified as modulators or non-modulators by previously established criteria, all seven non-modulators were FH+, and seven of nine FH+ subjects were non-modulators. This association between non-modulation and family history of hypertension is significant (p = 0.021). To further clarify the association between non-modulation and family history of hypertension, we have studied the renal blood flow response to Ang II in 31 hypertensive siblings from 14 sibships. Twenty-five of these 31 subjects (81%) behaved as non-modulators (p = 0.008 compared with expected value in an unselected hypertensive population). Additionally, strong concordance of non-modulation between sibling pairs was observed (p = 0.004). These findings indicate that a high proportion of FH+ subjects are non-modulators and that nonmodulation shows familial aggregation. These observations together strongly suggest that non-modulation is a heritable trait. Furthermore, the high prevalence of non-modulation in FH+ subjects further suggests that this trait may be one of the most important heritable factors in essential hypertension.