Journal of the Renin-Angiotensin- Aldosterone System October-December 2016: 1 –7 © The Author(s) 2016 Reprints and permissions: sagepub.co.uk/journalsPermissions.nav DOI: 10.1177/1470320316669880 jra.sagepub.com Creative Commons Non Commercial CC-BY-NC: This article is distributed under the terms of the Creative Commons Attribution-NonCommercial 3.0 License (http://www.creativecommons.org/licenses/by-nc/3.0/) which permits non-commercial use, reproduction and distribution of the work without further permission provided the original work is attributed as specified on the SAGE and Open Access pages (https://us.sagepub.com/en-us/nam/open-access-at-sage). Introduction The renin-angiotensin system (RAS) The RAS is a proteolytic cascade that consists of multiple enzymes and effector peptides. Angiotensin-converting enzyme (ACE) is one of the major enzymes in the RAS catalyzing the proteolytic conversion of the decapeptide angiotensin I (Ang I) to the octapeptide angiotensin II (Ang II, Ang 1-8).1,2 Ang II is involved in blood pressure and volume homeostasis as well as the development of hypertension, by promoting vascular smooth muscle cell migration, hypertrophy and delayed hyperplasia.2 All components of the RAS are present in human plasma with renin the rate-limiting enzyme of the RAS, catalyz- ing the conversion of pro-hormone angiotensinogen (10 N-terminal amino acids of the 452 amino acid-secreted protein) to Ang I.3 Ang I is the substrate for the production of the other angiotensin metabolites. Angiotensinogen is Quantification of systemic renin-angiotensin system peptides of hypertensive black and white African men established from the RAS-Fingerprint® JM van Rooyen1, M Poglitsch2, HW Huisman1, CMC Mels1, R Kruger1, L Malan1, S Botha1, L Lammertyn1, L Gafane1 and AE Schutte1,3 Abstract Objective: The objective of this study was to make use of a quantitative and qualitative approach comparing the systemic renin-angiotensin system (RAS) of hypertensive black and white African men by using RAS equilibrium analysis. Materials and methods: This sub-study involved 23 black (n = 15) and white (n = 8) hypertensive men aged 39.5–41 years, living in the North West Province of South Africa. The RAS-Fingerprinting was determined with LC-MS/MS quantification of angiotensin peptides. Blood pressure and other variables were determined with known methods. Results: The main finding of this study was the significant lower Ang I (<5.0 and 45.1 pg/ml; p = 0.005) and Ang II (15.6 and 123.9 pg/ml; p ⩽ 0.001) encountered in the hypertensive black African men compared to their white counterparts. Levels of Ang 1-5 (downstream metabolite of Ang 1-7) (1.8 and 3.0 pg/ml), were detected in black and white hypertensive men, respectively. Conclusions: The observed differences between circulating RAS components, which are reflected via equilibrium angiotensin levels, point to a distinctive molecular regulation of the RAAS in the two study cohorts. The increased peripheral resistance observed in hypertensive black individuals might take over a dominant role in control of blood pressure in this study population. A novel highly sensitive LC-MS/MS method resolved the issue of peptide recovery variations during sample preparation by using internal standards for each individual angiotensin metabolite. Keywords RAS-Fingerprint, renin, blacks, whites, RAS peptides Date received: 12 April 2016; accepted: 22 July 2016 1 Hypertension in Africa Research Team (HART), North-West University, Potchefstroom campus, South Africa 2Attoquant Diagnostics, Austria 3 MRC Extra Mural Unit: Hypertension and Cardiovascular Disease, North-West University, South Africa Corresponding author: JM van Rooyen, Hypertension in Africa Research Team (HART); School for Physiology, Nutrition, and Consumer Sciences, North- West University, Gerrit Dekker Street, Potchefstroom Campus, Potchefstroom, North West Province, 2520, South Africa. Email: johannes.vanrooyen@nwu.ac.za 669880 JRA0010.1177/1470320316669880Journal of the Renin-Angiotensin-Aldosterone SystemVan Rooyen et al. research-article2016 Original Article 2 Journal of the Renin-Angiotensin-Aldosterone System produced by the liver and secreted to the circulation, gen- erating a pool of angiotensinogen with concentrations in humans normally in a range of 5–50 µg/ml (100–1000 nM).3 Typical baseline values for plasma renin activity (PRA) in humans range between 0.1 and 2.35 (nmol/l)/h,4 while PRA values up to 20 (nmol/l)/h might be reached under pathologic conditions or on treatment with RAS blockers.5,6 Concentration and post-translational modifications of angi- otensinogen can affect PRA.7 High renin levels result in increased Ang II formation, could be detrimental to the vasculature and may play a role in hypertension, stroke, retinal detachment, myocardial infarction, heart and kidney failure, renal fibrosis, nephrop- athy and albuminuria.3,8,9 However, Opie and Seedat10 suggested that low plasma renin might also be one of the contributing factors to hypertension in sub-Saharan black populations and ascribed the low renin levels to be envi- ronmental in origin. The trend toward low renin levels may also be due to abnormalities such as excessive renal sodium reabsorption,10–12 reduction in the rate of renin secretion13 and genetic abnormalities in the RAS or related genes.10 It seems that not only high renin states but also low renin hypertension is associated with detrimental end-organ damage and a worse prognosis compared to hypertension with normal renin levels.14,15 A novel method of RAS analysis The biochemical analysis of the RAS represents a major challenge to analytical procedures, as it is well known that the quantification of angiotensin peptides is associated with technical issues. A novel highly sensitive liquid chromatography-mass spectrometry (LC-MS)/MS method1 resolved the issue of peptide recovery variations during sample preparation by using internal standards for each individual angiotensin metabolite.1 Internal standards are spiked to each sample before starting extraction proce- dures and are simultaneously detected in the final readout using an MS/MS analyzer operated in-line with an ultra- performance LC unit, which allows highly accurate quan- tification of angiotensin metabolites in tissue and plasma samples. The second major obstacle in biochemical evalua- tion of the RAS in patients is represented by pre-analytical variations. Angiotensin peptides are components of a rapidly flowing metabolic pathway characterized by the ongoing formation and degradation of individual angioten- sin metabolites in vivo. Standard procedures are aiming to block all enzymes involved in this metabolism during blood collection. This is a valid approach if it can be ensured that the inhibitor cocktail used contains all inhibi- tors necessary to block all angiotensin-processing enzymes involved in peptide metabolism, which is not achieved by using commercially available protease inhibitor tubes, usually lacking appropriate renin or aminopeptidase inhib- itors. Beside the qualitative composition of these protease inhibitor cocktails, the blood collection process itself can result in artifacts if mixing the inhibitor cocktail with the blood sample takes too long, which is a critical issue in animal studies using mice. We followed a quantitative and qualitative approach comparing the systemic RAS of hypertensive black and white African men by using RAS equilibrium analysis. Equilibrium analysis provides a valid alternative to the measurement of circulating angiotensin levels and can be measured in standard Li-heparin or serum samples. Equilibrium angiotensin profiles are composed of absolute levels of up to 10 angiotensin metabolites determined in a single sample and therefore provide an integrated picture of the activation state and enzymatic properties of the systemic RAS, which serves as a substrate supply for RAS enzymes on endothelial surfaces and in tissues. Methods and materials Study design and participant selection This is a sub-study of the South African study regarding the role of Sex, Age and Ethnicity on Insulin sensitivity and Cardiovascular function (SAfrEIC) study. This sub-study involved 23 black (n = 15) and white (n = 8) hypertensive men aged 39.5–41 years, living in the North West Province of South Africa. Exclusion criteria for this study were: previously diagnosed with diabetes (type 1 and 2), heart disease (bypass surgery, myocardial infarction or angina), stroke, asthma or any other serious medical conditions or use of any chronic medication. The inclusion criteria were: apparently healthy men and the hypertensives included in this sub-study were newly diagnosed after the study commenced. Newly diagnosed hypertensives who received medications that could interfere with the RAS were excluded in the analysis of this sub-study. The Ethics Committee of the North-West University, Potchefstroom campus, approved this study. Before being recruited, all interested participants were fully informed about the objectives and procedures of this study. An inter- preter was available to relay the information to individuals in their home language. Written informed consent was obtained from all individuals who decided to participate. Organizational procedures Participants reported to the Metabolic Unit facility on the Potchefstroom campus of the North-West University at 07:00 a.m. All the participants were introduced to the set-up and after the organizational procedures were explained to them, they all signed informed consent forms. Individuals received a participant sheet that guided them through the different research stations where the various measurements were performed. During the course of the morning, basic health and demographic questionnaires were completed, a fasting blood sample was taken and anthropometric measurements were performed. Afterwards blood pressure and pulse wave velocity measurements van Rooyen et al. 3 were taken with a Finometer and a Complior device. When all questionnaires and cardiovascular measurements were completed, each participant received a small financial compensation for travel purposes, as well as a breakfast. In the event of an individual being newly identified with hypertension or diabetes, individuals were referred to their local clinic, hospital or physician. Participants received a short report containing their health information. Biochemical analysis Serum high-sensitivity C-reactive protein (CRP), creatinine and gamma-glutamyltransferase (GGT) were analyzed with the Konelab20iTM auto-analyzer (Thermo Fisher Scientific, Vantaa, Finland). The serum amino-terminal pro-hormone B-type natriuretic peptide (NT-proBNP) levels were deter- mined with an electrochemiluminescence immunoassay (Elecsys 2010, Roche Diagnostics, Mannheim, Germany). Equilibrium RAS-Fingerprint analysis: Quantification of angiotensin metabolites in equilibrated serum Serum was obtained by centrifugation (2000 g, 4°C, 10 min) and stored at -80°C until shipped for analysis. Following ex vivo incubation at 37°C for one hour (pH = 7.4), serum was stabilized and subjected to LC-MS/ MS quantification of equilibrium angiotensin peptide levels (Attoquant Diagnostics, Vienna, Austria). Briefly, stable-isotope-labeled internal standards for angiotensin metabolites (Ang I, Ang 1-9, Ang II, Ang 2-8, Ang 3-8, Ang 1-7, Ang 1-5, Ang 2-7, Ang 3-7 and Ang 2-10) were added to the samples at a concentration of 200 pg/ml each. Following C18-based solid-phase-extraction, participants underwent LC-MS/MS analysis using a reverse-phase ana- lytical column (Acquity UPLC® C18, Waters) operating in line with a XEVO TQ-S triple quadrupole mass spec- trometer (Waters) in multiple reaction monitoring (MRM) mode. Two different mass transitions were measured per peptide, and angiotensin concentrations were calculated by relating endogenous peptide signals to internal standard signals under consideration of the corresponding response factors determined by sample specific calibration. A signal- to-noise ratio of 10 was considered as the quantification threshold for endogenous peptide signals, resulting in indi- cated lower levels of quantification. Equilibrium RAS analysis, which has been used in this study, does not require any stabilization during sample col- lection, allowing standardized analysis of clinical samples. Following separation of serum using standard serum tubes, samples were frozen and shipped for analysis. Following rapidly thawing of the serum, the peptide cascade was allowed to re-establish under controlled pH at 37°C. Angiotensinogen is present in a vast excess, resulting in a constant Ang I formation rate that leads to the estab- lishment of stable equilibrium levels of downstream angiotensin metabolites, which are readily formed as all angiotensin metabolizing enzymes are still active in the sample and present at huge amounts when compared to the very low concentrations of angiotensins, which are in the picomolar range. After reaching equilibrium, where the formation and the degradation rate of each individual pep- tide are equal, these levels can be rapidly and effectively stabilized and are further subjected to LC-MS/MS analysis as described above. The combination of equilibrium analysis with LC-MS/MS analysis is compatible with frozen hepa- rin plasma and serum samples and can be used to access the biochemical state of the RAS at the patient-specific level without pre-analytical or methodological obstacles. Anthropometric measurements Body height was measured using the Invicta Stadiometer (IP 1465, London, UK). Body mass was measured using a digital scale (Precision Health Scale, A & D Company, Japan) in order to calculate the body mass index (BMI).16 The Baecke physical activity questionnaire was employed to obtain the Total Activity Index of each participant. Cardiovascular measurements Pulse wave velocity (PWV) was measured using the Complior SP apparatus (Artech Medical, Pantin, France). The following distance was measured on the left side of each participant: carotid dorsalis-pedis (from the supraster- nal notch to the pedalis artery in the foot) distance. The subtraction method was used—the distance from the carotid artery to suprasternal notch was subtracted from the distal measurement. The PWV was measured while the participant was in a supine position. A five-minute continuous measurement of cardiovascu- lar variables using the Finometer™ device (FMS, Finapres Measurement Systems, Amsterdam, Netherlands)17,18 was taken and analyzed with the Beatscope 1.1 software pro- gram. This device computed all cardiovascular variables and stored the data in computer files. The information was further integrated to obtain the systolic (SBP) and diastolic blood pressure (DBP), arterial Windkessel compliance (Cwk) and total peripheral resistance (TPR) of each individual. Statistical analysis The data were statistically analyzed by making use of the Statistica 13 software (StatSoft Inc, Tulsa, OK, USA). Data are presented as mean values or median values with lower and upper quartiles. Because of the small sample, non-parametric statistics were used. To compare two independent sample groups, the Mann-Whitney U Test was used to determine significance. Probability values of p < 0.05 were regarded as significant. Spearman rank order correlations were also determined. 4 Journal of the Renin-Angiotensin-Aldosterone System Results From Table 1 it is evident that the white men were overweight compared to their black counterparts (30.1 vs. 20.7 kg/m2, p ⩽ 0.001). No differences were encountered in the Total Activity Index if black and white participants are compared. The blood pressures of both groups are in the hypertensive range (⩾140 mmHg and/or ⩾90 mmHg) according to the European Society of Hypertension guide- lines.19 Heart rate (HR) (64 vs. 61 beats/min, p = 0.028) and TPR (1.33 vs. 1.01 mmHg.s/ml, p = 0.047) were sig- nificantly higher in the black- compared to the white men, and the Cwk was significantly lower in the black compared to the white men (1.38 vs. 2.43 ml/mmHg, p = 0.002). The c-dPWV was significantly higher in the black men com- pared to their white counterparts (9.55 vs. 8.16 m/s, p = 0.001). From the equilibrium RAS-Fingerprint (Figure 1), Ang I and Ang II were significantly lower in the black men compared to their white counterparts (Median values: Ang I, <5 vs. 45.1 pg/ml, p = 0.005; Ang II, 15.6 vs. 123.9 pg/ml, p ⩽ 0.001). Ang 1-5 and Ang 3-8 did not differ significantly, although these downstream metabolites of Ang II were detected only in samples from individuals with elevated RAS activity characterized by Ang II levels ranging in the upper quartile. There are both in black and white hypertensive groups detectable levels of Ang 1-5, which is the downstream metabolite of Ang 1-7 that can be used as a surrogate for an alternative RAS pathway in the absence of ACE inhibition. The GGT was significantly higher in the black compared to the white men (78.9 vs. 41.4 U/l, p = 0.023). The creatinine clearance was significantly lower in the black men compared to the white men (1.52 vs. 1.72 ml/min, p = 0.005). The NT-proBNP appeared to be higher in the black compared to the white hypertensives although the differences were not significant. Angiotensin II correlated inversely and borderline significant with NT-proBNP only in the black hypertensives (see Table 2), (Spearman R= −0.472, p = 0.076). Discussion The aim of this study was to explore the differences in the RAS of hypertensive black and white men by using a novel method for determining the effector molecules. The main finding of this study is the significant lower Ang I and Ang II encountered in the hypertensive black African men com- pared to their white counterparts. This result is in accord- ance with the common notion that black individuals are more prone to have low renin hypertension10–12 accompa- nied by a suppressed RAS than white individuals. From the results of this study it is further shown that the black men had stiffer blood vessels (higher c-dPWV) than whites, also reported in the literature;20 lower vascular compliance and higher TPR compared to their white counterparts. From the Sympathetic activity and Ambulatory Blood Pressure in Africans (SABPA) study it is also evident that in low-renin normotensive black participants a higher TPR was reported compared to high-renin participants.21 In the regression model from the mentioned study the TPR contributed to the albumin-creatinine ratio, a marker of Table 1. Characteristics of the hypertensive black and white men. Variable Black men n = 15 White men n = 8 p valuea Age (years) 41.0 (35.0–44.0) 39.5 (31.5–48.0) 0.728 BMI (kg/m2) 20.7 (18.2–23.7) 30.1 (27.8–31.7) <0.001 Baecke TAI 8.9 (7.9–9.9) 8.0 (5.9–8.9) 0.101 Cardiovascular variables SBP (mmHg) 151.2 (139.0–170.9) 144.0 (138.2–150.6) 0.506 DBP (mmHg) 90.3 (82.7–98.7) 83.3 (80.8–92.3) 0.238 HR (beats/min) 64 (62.4–71.6) 61 (55.2–65.6) 0.028 TPR (mmHg.s/ml) 1.33 (1.05–1.48) 1.01 (0.90–1.31) 0.047 Cwk (ml/mmHg) 1.38 (1.26–1.82) 2.43 (2.26–2.60) 0.002 c-dPWV (m/s) 9.55 (8.76–10.45) 8.16 (6.80–8.60) 0.001 Biochemical variables Ang I (pg/ml) <5.0 (2.5–17.0) 45.1 (22.3–51.0) 0.005 Ang II (pg/ml) 15.6 (9.0–24.0) 123.9 (70.5–179.5) <0.001 CRP (mg/l) 2.12 (1.26–4.08) 1.30 (0.47–2.38) 0.265 GGT (U/l) 78.9 (49.3–135.7) 41.4 (25.1–74.8) 0.023 Creatinine clearance (ml/min) 1.52 (1.17–1.60) 1.72 (1.66–2.20) 0.005 NT-proBNP (ng/ml) 29.6 (2.5–63.7) 16.4 (10.4–18.5) 0.428 Data presented as median (lower; upper quartile). BMI: body mass index (kg/m2); Baecke TAI: Baecke Total Activity Index; SBP, DBP: systolic and diastolic blood pressure (mmHg), respectively; HR: heart rate; TPR: total peripheral resistance (mmHg.s/ml); Cwk: Windkessel compliance (ml/mmHg); c-dPWV: carotid-distalis pulse wave velocity; Ang I and Ang II: (angiotensin I and angiotensin II (pg/ml)); CRP: C-reactive protein (mg/l); GGT: gamma-glutamyltransferase; NT-proBNP: N-terminal pro-hormone B-type natriuretic peptide. a2*1-sided exact p value. van Rooyen et al. 5 end-organ damage.21 These findings strengthen the notion that in individuals with low-renin hypertension an addi- tional cardiovascular risk may be posed. In our study the median value of NT-proBNP was higher in the black compared to the white hypertensive men although not significant (29.6 (2.5–63.7) vs. 16.4 ng/ml (10.4–18.5), p = 0.428) due to the large variation in the data. These elevated NT-proBNP levels reflect higher volume loading in the hypertensive black men. The NT-proBNP, which is a hemodynamic marker of volume loading,22,23 is higher in black compared to white men.24 In our study Ang II correlated borderline with NT-proBNP only in the black hypertensives. Because of the higher volume loading and the myogenic phenomenon, it seems Figure 1. The Equilibrium RAS-Fingerprint of 15 hypertensive black (left) and eight hypertensive white (right) men (Caucasian) (untreated with medications that could interfere with the renin-angiotensin system (RAS)). The mean equilibrium concentrations of indicated angiotensin metabolites are given in the graphs in pg/ml serum. Sphere sizes represent the concentrations and enzymatic pathways are indicated as blue arrows. The enzyme activities indicated are: AP: aminopeptidase; NEP: neutral endopeptidase; DAP: di-aminopeptidase; ACE: angiotensin-converting enzyme. The numbers in brackets indicate the sequence of the corresponding angiotensin metabolite, starting with the decapeptide Angiotensin I (Ang I). Table 2. Spearman rank order correlations of Angiotensin II in hypertensive black and white men. Variables Black men (n = 15) White men (n = 8) Spearman R p value Spearman R p value BMI (kg/m2) −0.449 0.093 −0.238 0.570 SBP (mmHg) −0.320 0.246 −0.238 0.570 DBP (mmHg) −0.057 0.839 −0.357 0.385 TPR (mmHg.s/ml 0.417 0.122 −0.286 0.493 c-dPWV (m/s) −0.257 0.356 −0.429 0.289 NT-proBNP (ng/ml) −0.472 0.076 −0.238 0.570 GGT (U/L) −0.145 0.605 0.071 0.867 CRP (mg/l) 0.206 0.460 −0.119 0.779 BMI: body mass index; SBP, DBP: systolic and diastolic blood pressure, respectively; TPR: total peripheral resistance; c-dPWV: carotid-distalis pulse wave velocity; NT-proBNP: N-terminal pro-hormone B-type natriuretic peptide; GGT: gamma-glutamyltransferase; CRP: C-reactive protein. P values ⩽0.05 regarded as significant. 6 Journal of the Renin-Angiotensin-Aldosterone System that a physiological protective mechanism is in action where the resistance to blood flow in arterioles increases in order to protect the peripheral tissue and capillaries against edema or rupture25 with the long-term result of higher blood pressure. From the literature it is also evident that African Americans exhibit larger systemic vascular resist- ance compared to white individuals and the peripheral resistance may play a larger role in regulation of ambula- tory blood pressure.26 This is confirmed in our study at least in hypertensive black men because the TPR is signifi- cantly higher in the black men with suppressed renin and low Ang II levels compared to the white men. The findings of this study should be interpreted within its strengths and limitations. To the best of our knowledge it is the first study in which equilibrium RAS-Fingerprint analysis was employed for simultaneous biochemical characterization of the RAS peptides in a black and white population from South Africa and holds promise to under- stand the RAS better in different ethnic groups as well as in different pathologic states. The systemic RAS peptides and the interaction between components provide new therapeutic targets1,27 for treatment of cardiovascular diseases like hypertension in this population group. Our results proved the compatibility of standard collected serum samples with patient-specific biochemical charac- terization of endogenous angiotensin metabolism using LC-MS/MS. We further support previous studies reporting low-renin hypertension in black African men showing that equilibrium Ang I and Ang II peptide levels are signifi- cantly lower in the black population.28 The small sample size, which is also reflected by the differences in median and mean values for equilibrium angiotensin peptides (Table 1, Figure 1), as well as the fact that aldosterone and sodium intake and/or excretion were not determined, are limitations of the study. The BMI differences observed in the two study cohorts might appear to be a confounder variable of the study. Functional interactions between the renin-angiotensin-aldosterone system (RAAS) and obesity have been established in previous studies and the local RAAS in adipose tissue has been discussed in terms of its contribution to hypertension.29 Importantly, the systemic RAAS, represented by plasma-circulating components, were clearly shown not to correlate with BMI,30 proving that the effects observed in our study are not related to differences in the BMI of investigated cohorts although in a large study conducted in African Americans published recently,31 it was shown that visceral adiposity is associ- ated with components of the RAAS in African Americans. The observed differences between circulating RAS components, which are reflected via equilibrium angioten- sin levels, point to a distinctive molecular regulation of the RAAS in the two study cohorts. Despite the low number of patients, the differences observed in equilibrium angioten- sin levels were highly significant indicating that profound differences in systemic RAAS biochemistry might be present. This could affect the efficacy of therapeutic approaches targeting the RAAS that are currently employed to treat hypertension in South Africa. The increased peripheral resistance observed in hyper- tensive black individuals might take over a dominant role in control of blood pressure in this study population, which could have resulted in an underrepresentation of the circu- lating RAAS in the control of blood pressure. Acknowledgements We thank Roche Diagnostics for providing the test kits for NT-proBNP. We also thank the participants in this sub-study. Declaration of conflicting interests Dr M Poglitsch has stocks in Attoquant Diagnostics GmbH. The other authors have nothing to declare. Funding The overarching SAfrEIC study was supported by the South African National Research Foundation (NRF) Grant (GUN 2073040), and the Medical Research Council (South Africa). Options, findings, conclusions and recommendations expressed in this material are those of the authors and the NRF does not accept any liability in this regard. References 1. Poglitsch M, Domenig O, Schwager C, et al. Recombinant expression and characterization of human and murine ACE2: Species-specific activation of the alternative renin- angiotensin-system. Int J Hypertens 2012; 2012: 428950. 2. Nguyen Dinh Cat A and Touyz RM. A new look at the renin-angiotensin system—focusing on the vascular system. Peptides 2011; 32: 2141–2150. 3. Alderman MH, Madhavan S, Ooi WL, et al. Association of the renin-sodium profile with the risk of myocardial infarc- tion in patients with hypertension. N Engl J Med 1991; 324: 1098–1104. 4. Kerstens MN, Kobold AC, Volmer M, et al. Reference val- ues for aldosterone-renin ratios in normotensive individuals and effect of changes in dietary sodium consumption. Clin Chem 2011; 57: 1607–1611. 5. Kashiwabara H, Inaba M, Itabashi A, et al. A case of renin- producing juxtaglomerular tumor: Effect of ACE inhibitor or angiotensin II receptor antagonist. Blood Press 1997; 6: 147–153. 6. Hollenberg NK, Fisher ND, Nussberger J, et al. Renal responses to three types of renin-angiotensin system block- ers in patients with diabetes mellitus on a high-salt diet: A need for higher doses in diabetic patients? J Hypertens 2011; 29: 2454–2461. 7. Zhou A, Carrell RW, Murphy MP, et al. A redox switch in angiotensinogen modulates angiotensin release. Nature 2010; 468: 108–111. 8. Probstfield JL and O’Brien KD. Progression of cardiovascu- lar damage: The role of renin-angiotensin system blockade. Am J Cardiol 2010; 105 (1 Suppl): 10A-20A. 9. Melnyk RA, Tam J, Boie Y, et al. Renin and prorenin activate pathways implicated in organ damage in human mesangial cells independent of angiotensin II production. Am J Nephrol 2009; 30: 232–243. van Rooyen et al. 7 10. Opie LH and Seedat YK. Hypertension in Sub-Saharan African populations. Circulation 2005; 112: 3562–3568. 11. Why the treatment of hypertension has become such a deplorable fiasco, Part 1 and Part II, http://articles.mercola. com/sites/articles/archive/2003/12/03/hypertension-part- two.aspx (accessed 16 June 2010). 12. Bochud M, Staessen JA, Maillard M, et al. Ethnic differ- ences in proximal and distal tubular sodium reabsorption are heritable in black and white populations. J Hypertens 2009; 27: 606–612. 13. Sagnella GA. Why is plasma renin activity lower in popula- tions of African origin? J Hum Hypertens 2001; 15: 17–25. 14. Duffy SJ, Biegelsen ES, Eberhardt RT, et al. Low-renin hypertension with relative aldosterone excess is associated with impaired NO-mediated vasodilation. Hypertens 2005; 46: 707–713. 15. Meade TW, Imeson JD, Gordon D, et al. The epidemiology of plasma renin. Clin Sci (London) 1983; 64: 273–280. 16. Norton K and Olds T. Anthropometrica. A textbook of body measurement for sports and health courses. Sydney: University of New South Wales Press, 1996. 17. Imholz BPM, Wieling W, van Montfrans GA, et al. Fifteen years experience with finger arterial pressure monitoring: Assessment of the technology. Cardiovasc Res 1998; 38: 605–616. 18. Schutte AE, Huisman HW, van Rooyen JM, et al. Validation of the Finometer device for measurement of blood pressure in black women. J Hum Hypertens 2004; 18: 79–84. 19. Mancia G, De Backer G, Dominiczak A, et al. Guidelines for the management of arterial hypertension: The Task Force for the Management of Arterial Hypertension of the European Society of Hypertension (ESH) and of the European Society of Cardiology (ESC). J Hypertens 2007; 25: 1105–1187. 20. Schutte AE, Reimann M, Huisman HW, et al. Ethnic differ- ences in arterial stiffness with aging. J Hypertens 2009; 27 (Suppl 4): S386. 21. van Rooyen JM, Schutte AE, Huisman HW, et al. End- organ damage in urbanized Africans with low plasma renin levels: The SABPA study. Clin Exp Hypertens 2014; 36: 70–75. 22. De Lemos JA, McGuire DK and Drazner MH. B-type natriuretic peptide in cardiovascular disease. Lancet 2003; 362: 316–322. 23. Weber M and Hamm C. Role of B-type natriuretic peptide (BNP) and NT-proBNP in clinical routine. Heart 2006; 92: 843–849. 24. Kruger R, Schutte R, Huisman HW, et al. NT-proBNP and potential vascular calcification in black and white Caucasian African men: The SAfrEIC study. Ethn Dis 2012; 22: 398–403. 25. Levy BI. New aspects in the mechanisms of hyperten- sion and the pathophysiology of the arterial tree. In: Safar ME (ed.) Macro- and microcirculation in hypertension. Philadelphia, PA: Lippincott Williams & Wilkins, 2005. 26. Sherwood A, Hughes JW and McFetridge J. Ethnic differ- ences in the hemodynamic mechanisms of ambulatory blood pressure regulation. Am J Hypertens 2003; 16: 270–273. 27. Koid SS and Campbell DJ. Evolving concepts of the renin- angiotensin system: Highlights from the pre-ISH 2012 sat- ellite meeting. J Renin Angiotensin Aldosterone Syst 2012; 14: 93–96. 28. Mayito J, Mungoma M, Kakande B, et al. Angiotensin II status and sympathetic activation among hypertensive patients in Uganda: A cross-sectional study. BMC Res Notes 2015; 8: 586. 29. Segura J and Ruilope LM. Obesity, essential hypertension and renin-angiotensin system. Public Health Nutr 2007; 10: 1151–1155. 30. O’Seaghdha CM, Hwang S, Vasan RS, et al. Correlation of renin angiotensin and aldosterone system activity with subcutaneous and visceral adiposity: The Framingham heart study. BMC Endocr Disord 2012; 12: 3. 31. Joseph JJ, Echouffo-Tcheugui JB, Kalyani RR, et al. Aldosterone, renin, and diabetes mellitus in African Americans: The Jackson Heart Study. J Clin Endocrin Metab 2016; 101: 1770–1778.