METHOD FOR THE DIAGNOSIS AND TREATMENT OF ESSENTIAL PRIMARY HYPERTENSION
The invention is in the field of molecular diagnosis of medical diseases and their treatment. More in particular, it provides methods and means for detecting hypertension, more in particular essential primary hypertension, even more in particular NOX5-dependent hypertension. The invention also provides methods for the treatment of hypertension, in particular essential primary hypertension, more in particular NOX5-dependent hypertension. The invention also provides theragnostics, wherein therapy is combined with diagnosis, more in particular wherein the level of NOX5 is determined in a sample from a subject and wherein the subject is treated with NOX5 inhibitors or compounds that decrease the levels of NOX5 if the NOX5 levels are above a certain threshold value. Further, the invention also provides theragnostics, wherein diagnosis is combined with therapy, more in particular wherein the (plasma) level of NOX5 is determined in a sample from a subject and wherein the subject is treated with NOX5 inhibitors or compounds that reverse the result of NOX5 activity in the subject, when the determined NOX5 level is exceeding a predetermined threshold level. Finally, the invention relates to an animal model suitable for developing diagnostic methods and therapeutic treatments for NOX5-dependent hypertension.
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The invention is in the field of molecular diagnosis of medical diseases and their treatment. More in particular, it provides methods and means for detecting hypertension, more in particular essential primary hypertension, even more in particular NOX5-dependent hypertension. The invention also provides methods for the treatment of hypertension, in particular essential primary hypertension, more in particular NOX5-dependent hypertension. The invention also provides theragnostics, wherein therapy is combined with diagnosis, more in particular wherein the level of NOX5 is determined in a sample from a subject and wherein the subject is treated with NOX5 inhibitors or compounds that decrease the levels of NOX5 if the NOX5 levels are above a certain threshold value. Further, the invention also provides theragnostics, wherein diagnosis is combined with therapy, more in particular wherein the (plasma) level of NOX5 is determined in a sample from a subject and wherein the subject is treated with NOX5 inhibitors or compounds that reverse the result of NOX5 activity in the subject, when the determined NOX5 level is exceeding a predetermined threshold level. Finally, the invention relates to an animal model suitable for developing diagnostic methods and therapeutic treatments for NOX5-dependent hypertension.
BACKGROUND OF THE INVENTIONHypertension is of major medical relevance as a risk factor for myocardial infarction, stroke and other chronic conditions and death [1]. With the exception of 5% of patients with secondary hypertension (due to renal artery stenosis, adrenal adenomas, pheochromocytomas and numerous single gene mutations involving renal transporters [2]), in the remaining 95% of all cases the cause of hypertension is not known. In these cases of so-called ‘essential primary hypertension’, treatments have to focus on symptomatic vasodilatory drug therapy and lifestyle management. Even this symptomatic antihypertensive therapy is sometimes ineffective, i.e. in treatment-resistant hypertension, and requires high number to treat with many patients still experiencing adverse outcomes such as stroke and myocardial infarction [3]. Resistant hypertension (RH) is defined by the American Heart Association [104] as: above-goal elevated blood pressure (BP) in a patient despite the concurrent use of three anti-hypertensive drug classes, commonly including a long-acting calcium channel blocker, a blocker of the renin-angiotensin system (angiotensin-converting enzyme inhibitor or angiotensin receptor blocker), and a diuretic. The antihypertensive drugs should be administered at maximum or maximally tolerated daily doses. RH also includes patients whose BP achieves target values on more than four anti-hypertensive medications. The diagnosis of RH requires assurance of anti-hypertensive medication adherence and exclusion of the “white-coat effect” (office BP above goal but out-of-office BP at or below target).
One molecular mechanism of hypertension that has been suggested for decades is oxidative stress, i.e. an unphysiological production of reactive oxygen species (ROS), which in blood vessels interferes with vasodilation by the endothelium-derived relaxing factor, nitric oxide (NO) [4]. No hypertension-relevant cellular source of ROS, however, has been identified to either prove this hypothesis or exploit it for a mechanism-based or even curative clinical therapy.
Recent genome-wide association studies (GWAS) [5] in search for hypertension risk genes point towards NADPH oxidases (NOX), the only known enzyme family dedicated to ROS formation, in particular the genes Nox4 and Nox5. This matches preclinical studies, excluding other vascular NOX isoforms i.e. NOX1 and NOX2 with respect to causing hypertension, unless animals are infused with pro-hypertensive agents [6-8]. With respect to NOX4, this isoform is widely expressed, but appears irrelevant for blood pressure or hypertension [9] but is rather vaso-protective [10]. With respect to NOX5, this enzyme is physiologically expressed in vascular endothelial cells of human blood vessels and may be associated with diabetic nephropathy [11-13]; mice expressing human NOX5 in vascular smooth muscle cells are, however, normotensive [14]. Thus, the role of NOX5 in hypertension remains as yet unclear.
In moving away from single targets, network medicine [15] predicts that for most in particular complex diseases not a single protein but protein modules, i.e. sub-graphs of the interactome, are in fact relevant [16-18]. Therefore, we set out to reinvestigate the association of NOX with hypertension and NO-dependent vasodilation using three complementing unbiased in-silico approaches and to validate any prediction both in mice and, if possible, also human patient samples.
SUMMARY OF THE INVENTIONThe invention relates to a novel method for diagnosing essential arterial hypertension in a subject, in particular NOX5-dependent hypertension in a subject, wherein the level of NADPH oxidase 5 (NOX5) is determined in a fluid or tissue sample from the subject, and wherein it is concluded that the subject has essential arterial hypertension, in particular NOX5-dependent hypertension, if the level of NOX5 is above a predetermined threshold level.
The invention also relates to a method for detection of a hypertension endotype in a human patient suffering from essential arterial hypertension, wherein said endotype is defined by an increased level of circulating NADPH oxidase 5 protein (NOX5) compared to the level of circulating NOX5 in a human subject not suffering from hypertension, the method comprising the steps of:
-
- (a) obtaining a fluid sample from the human patient who suffers from essential arterial hypertension, selected from the group comprising plasma, blood and serum, wherein the fluid sample comprises circulating endothelial microparticles;
- (b) isolating the endothelial microparticles from the fluid sample provided in step (a); and
- (c) measuring NOX5 in the endothelial microparticles of step (b) using a protein detection assay and determining the concentration of NOX5 in the fluid sample in pg NOX5 per ml fluid sample,
wherein it is concluded that the human patient suffers from the hypertension endotype if the concentration of NOX5 as determined in step (c) is at least 160 pg NOX5 per ml of the fluid sample.
In one embodiment, the invention therefore relates to a novel method for diagnosing a hypertension endotype in a subject wherein the level of NOX5 is determined in a fluid or tissue sample from the subject, preferably plasma sample, and wherein it is concluded that the subject has the hypertension endotype if the level of NOX5 is above a predetermined threshold level. The threshold level can be defined as the amount of NOX5 protein (enzyme) per volume, such as pg NOX5 per ml plasma of the hypertension endotype patient. The threshold level can also be defined as the NOX5 enzyme activity per volume, such as I.U. enzyme activity per ml plasma of the patient suffering from the endotype. This method identifies the subjects with a disease entity (endotype) that was previously a disease entity generally called treatment-resistant hypertension. Those cases of resistant hypertension patients suffering from the endotype as now defined by the inventors may now effectively be treated with NOX5 inhibitors or with compounds selected from the group consisting of sepiapterin, L-citrulline, L-arginine, tetrahydrobiopterin and folic acid. Those cases may now effectively be treated with NOX5 inhibitor setanaxib (2-(2-Chloropheny)-4-[3-(di-methylamino)phenyl]-5-methyl-1H-pyrazolo[4,3-c]pyridine-3,6-dione) or ML090 (5,12-dihydroquinoxalino(2,3-B)quinoxaline), with molecular structure
Further NOX5 inhibitors suitable for inhibiting NOX5 in the patients suffering from the hypertension endotype are for example anti-human NOX5 antibodies, or any binding domain(s) thereof or any binding fragment(s) thereof endowed with the ability to inhibit NOX5 enzyme activity, or an siRNA suitable for gene silencing of the human Nox5 gene. In addition, NOX5 inhibitors suitable for inhibiting NOX5 in the patients suffering from NOX5-dependent hypertension are for example perphenazine, ML171 and VAS2870.
The invention also relates to a method for detection of a hypertension endotype in a human patient suffering from essential arterial hypertension, wherein said endotype is defined by an increased level of circulating NADPH oxidase 5 protein (NOX5) compared to the level of circulating NOX5 in a human subject not suffering from hypertension, the method comprising the steps of:
-
- (a) obtaining a plasma sample from the human patient who suffers from essential arterial hypertension; and
- (b) measuring NOX5 in the plasma sample of step (a) using a protein detection assay and determining the concentration of NOX5 in the plasma sample in pg NOX5 per ml plasma,
wherein it is concluded that the human patient suffers from the hypertension endotype if the concentration of NOX5 as determined in step (b) is at least 160 pg NOX5 per ml of the plasma sample.
Alternatively, the threshold level for the NOX5 is defined in enzyme activity per ml plasma.
Further, the invention relates to a method for the detection of a hypertension endotype in a human patient suffering from essential arterial hypertension, wherein said endotype is hypertension characterized by being
-
- accompanied by renal vascular leakage as established by the occurrence of microalbuminuria; or
- associated with the risk for developing renal vascular leakage apparent as development of microalbuminuria,
the method comprising the steps of: - (a) obtaining a fluid sample from the human patient who suffers from essential arterial hypertension, selected from the group comprising plasma, blood and serum, wherein the fluid sample comprises circulating endothelial microparticles;
- (b) isolating the endothelial microparticles from the fluid sample provided in step (a); and
- (c) measuring NADPH oxidase 5 protein (NOX5) in the endothelial microparticles of step (b) using a protein detection assay and determining the concentration of NOX5 in the fluid sample in pg NOX5 per ml fluid sample,
wherein it is concluded that the human patient has the hypertension endotype if the concentration of NOX5 is at least 160 pg NOX5 per ml of the fluid sample. Alternatively, the threshold level for the NOX5 is defined in enzyme activity per ml plasma.
The invention further relates to a compound selected from the group consisting of sepiapterin, L-citrulline, L-arginine, tetrahydrobiopterin, folic acid and a NOX5 inhibitor, in particular a NOX5 inhibitor based on quinoxaline such as NOX5 inhibitor 5,12-dihydroquinoxalino(2,3-B)quinoxaline (ML090), for use in the treatment of a subject with essential arterial hypertension, in particular with NOX5-dependent hypertension. Another suitable NOX5 inhibitor is setanaxib (2-(2-Chloropheny)-4-[3-(di-methylamino)phenyl]-5-methyl-1H-pyrazolo[4,3-c]pyridine-3,6-dione). Further NOX5 inhibitors suitable for inhibiting NOX5 in the patients suffering from NOX5-dependent hypertension are for example anti-human NOX5 antibodies, or any binding domain(s) thereof or any binding fragment(s) thereof endowed with the ability to inhibit NOX5 enzyme activity, or an siRNA suitable for gene silencing of the human Nox5 gene. In addition, NOX5 inhibitors suitable for inhibiting NOX5 in the patients suffering from the NOX5-dependent hypertension are for example perphenazine, ML171 and VAS2870. The invention relates to a method for treating NADPH oxidase 5 (NOX5)-dependent hypertension comprising administering one or more of the compounds sepiapterin, folic acid, L-citrulline, L-arginine and tetrahydrobiopterin to a human patient suffering from essential arterial hypertension, wherein the human patient has an NOX5 plasma concentration of at least 160 pg NOX5 per ml plasma. In particular, comprising administering sepiapterin.
The invention relates to a method for treating NADPH oxidase 5 (NOX5)-dependent hypertension comprising administering an NOX5 inhibitor to a human patient suffering from essential arterial hypertension, wherein the human patient has an NOX5 plasma concentration of at least 160 pg NOX5 per ml plasma. In particular, comprising administering NOX5 inhibitor 5,12-dihydroquinoxalino(2,3-B)quinoxaline (ML090) to a human patient suffering from essential arterial hypertension, wherein the human patient has an NOX5 plasma concentration of at least 160 pg NOX5 per ml plasma. Another suitable NOX5 inhibitor is setanaxib (2-(2-Chloropheny)-4-[3-(di-methylamino)phenyl]-5-methyl-1H-pyrazolo[4,3-c]pyridine-3,6-dione). Further NOX5 inhibitors suitable for inhibiting NOX5 in the patients suffering from the hypertension endotype are for example anti-human NOX5 antibodies, or any binding domain(s) thereof or any binding fragment(s) thereof endowed with the ability to inhibit NOX5 enzyme activity, or an siRNA suitable for gene silencing of the human Nox5 gene. In addition, NOX5 inhibitors suitable for inhibiting NOX5 in the patients suffering from NOX5-dependent hypertension are for example perphenazine, ML171 and VAS2870.
In addition, the invention relates to administering an effective amount of one or more of sepiapterin, folic acid, L-citrulline, L-arginine and tetrahydrobiopterin to a human patient to treat NADPH oxidase 5 (NOX5)-dependent hypertension. In particular administering sepiapterin.
The invention also relates to administering an effective amount of an NOX5 inhibitor, in particular 5,12-dihydroquinoxalino(2,3-B)quinoxaline (ML090), to a human patient to treat NADPH oxidase 5 (NOX5)-dependent hypertension.
The invention further relates to a compound selected from the group consisting of sepiapterin, L-citrulline, L-arginine, tetrahydrobiopterin, folic acid and a NOX5 inhibitor, in particular a NOX5 inhibitor based on quinoxaline such as NOX5 inhibitor 5,12-dihydroquinoxalino(2,3-B)quinoxaline (ML090), for use in the treatment of a subject with essential arterial hypertension, in particular with NOX5-dependent hypertension. Another suitable NOX5 inhibitor is setanaxib (2-(2-Chloropheny)-4-[3-(di-methylamino)phenyl]-5-methyl-1H-pyrazolo[4,3-c]pyridine-3,6-dione). Further NOX5 inhibitors suitable for inhibiting NOX5 in the patients suffering from the NOX5-dependent hypertension are for example anti-human NOX5 antibodies, or any binding domain(s) thereof or any binding fragment(s) thereof endowed with the ability to inhibit NOX5 enzyme activity, or an siRNA suitable for gene silencing of the human Nox5 gene. In addition, NOX5 inhibitors suitable for inhibiting NOX5 in the patients suffering from the NOX5-dependent hypertension are for example perphenazine, ML171 and VAS2870.
In a further embodiment, the invention relates to the use of an aged NOX5 knock-in an animal model to discover and develop therapeutics and diagnostics for the use in NOX5- and uncoupled NOS-dependent (essential arterial) hypertension.
The invention also relates to the use of a mouse with knocked-in human Nox5 gene to discover and develop therapeutics and methods for detection, for the use in NOX5-dependent hypertension in a subject.
A. Femoral arteries of aged KI mice (n=9) pre-contracted with phenylephrine (Phe) had less responsiveness to acetylcholine (Ach)-induced relaxation compared to WT (n=9) while pre-treatment with sepiapterin (100 μM) improved relaxation in KI (n=4) which was not different from WT (n=3).
B. Saphenous arteries of aged KI mice (n=9) pre-contracted with Phe showed no difference in Ach-induced relaxation compared to WT (n=8). Myograph data were analyzed by two-way ANOVA followed by Sidak's multiple comparisons test.
C. Schematic representation of NOX5-induced age-dependent hypertension. In ageing, endothelial NOX5 is activated and interferes with normal NO-cGMP signalling which results in impaired vascular smooth muscle relaxations and raised blood pressure.
Abbreviations: EC, endothelial cell; ET-1, endothelin-1; H4Bip, tetrahydrobiopterin; NA, noradrenaline; NOS3, endothelial nitric oxide synthase; SMC, smooth muscle cell; sGC, soluble guanylate cyclase; SN, sympathetic nerve. All data are represented as mean±S.E.M. of n individual animals ***P<0.001.
To explore the possible link between NOX isoforms and hypertension and NO-dependent vasodilation, we constructed a pruned molecular subnetwork from the first neighbours of NOX family members and nitric oxide-cyclic GMP related proteins as seed nodes in the experimentally validated interactome obtained from the IID [19] interactome database. These included NOX1, NOX3, NOX4, NOX5, NOS1, NOS3, GUCYA1, GUCYA2, GUCYB1, PDE5A, PDE9A and PRKG1, but not NOX2 and NOS2.
The resulting subnetwork was further pruned according to the subnetwork-participation-degree (SPD) to correct for hub nodes (i.e. proteins that occurred mainly because of their high number of interactions in the whole network). This resulted in a disease module consisting of several connected components, which revealed that al NOX isoforms but NOX5 were excluded as close neighbour of endothelial NO-cyclic GMP signalling. NOX5 fell into the same connected component with the genes encoding the NO receptor, GUCYA1, GUCYA2 and GUCYB1, and with endothelial NOS (NOS3) (
To cross-check our in-silico findings of a NOX disease module, we employed two additional computational network module identification methods, global modularity optimization and agglomerative local search, both of which have been top-performers in the recent Module Identification DREAM Challenge [21]. In brief, the global modularity optimization approach combines multiple module detection algorithms to avoid suboptimal partitions resulting from individual algorithms [22]. The agglomerative local method uses the SPICi algorithm [23] to optimize local density of modules around seed nodes. With all three in-silico methods we reached the same conclusion: Exclusion of all NOX genes, except NOX5, as a direct neighbour of endothelial nitric oxide-cyclic GMP signalling (
To test this causal endothelial NOX5 hypothesis for human hypertension, we enrolled consecutive outpatients with essential primary hypertension and a baseline estimated glomerular filtration rate (eGFR) 230 mL/min/1.73 m2. Study subjects were divided into 3 groups, healthy (n=10), hypertensive patients with normo-albuminuria (n=20) and hypertensive patients with moderately increased albuminuria (previously termed microalbuminuria) (n=20). The baseline characteristics of the patients are listed in Table 1. To measure NOX5 protein levels, circulating endothelial microparticles, i.e. membrane vesicles that are released from endothelial cells upon cellular activation or cell death and carry endothelial proteins [24], were isolated from plasma of the participants (
In Table 1, the triglycerides are displayed in mg/dL; glucose levels are in mg/dL; uric acid is in mg/dL; adiponectin is in mg/dL.
We tested the possible role of NOX5 in endothelial NO-cGMP signalling dysfunction and hypertension in mice. Mice, however, lack the Nox5 gene. We therefore analyzed a knock-in mouse model expressing human Nox5 in its physiological endothelial cell location [31] (
Taken together, our observations indicate that in mice, expression of NOX5 in the endothelium leads, upon aging, to a selective elevation of systolic arterial blood pressure. Having established the potential of NOX5 to induce a hypertensive phenotype, we proceeded to test the mechanistic link to vascular NO-cGMP signalling as suggested from the in-silico network analysis.
In thoracic aorta, femoral artery and saphenous artery isolated from aged knock-in (KI) and wild-type (WT) mice of both genders (n=9), we analyzed the structural, smooth muscle and endothelial vasomotor properties. Collectively, these blood vessels cover the entire range of large elastic conduit, muscular conduit and small muscular resistance-sized arteries, respectively. In thoracic aorta, femoral artery and saphenous artery of the aged animals, the relation between resting wall tension and arterial lumen diameter did not differ between KI and WT mice (
To test the effect of endothelial NOX5 on endothelium-dependent, NO-cGMP mediated relaxation, arterial segments were pre-contracted by either depolarization (K+), α1-adrenergic activation (phenylephrine), or endothelin-1; vaso-relaxation was then induced by acetylcholine (Ach) the classical endothelium-derived relaxing factor stimulant [45]. In femoral arteries, irrespective whether pre-contracted with K+, phenylephrine or endothelin-1, the amplitudes of Ach-induced relaxing responses were significantly smaller in KI compared to WT mice (
In segments of thoracic aorta and femoral artery contracted with 258 nM endothelin-1, the relaxing effects of Ach were reversed by 100 μM L-NAME (a pharmacological inhibitor of NO synthases) and this did not differ significantly between preparations of KI and WT mice (
To check whether this caliber specific effect on vasomotor function was due to differential expression of NOX5 along the systemic arterial tree, we measured NOX5 gene expression by quantitative PCR. There was, however, no difference in NOX5 gene expression between thoracic aorta, femoral arteries and saphenous arteries of NOX5 KI mice (
We next tested whether, alternatively, chronic changes in the underlying arterial smooth muscle layer could have contributed to the observed blood pressure and vasomotor phenotypes in aged NOX5 KI mice. Contractile responses to K+ and the sensitivity and maximal responsiveness to phenylephrine and endothelin-1 did, however, not differ between KI and WT mice in all arterial segments (
To test which component of NO-cGMP signalling was most likely affected, we tested an uncoupling effect on endothelial NO synthase [50] or an oxidative damage of the NO receptor, soluble guanylate cyclase yielding oxidized or heme-free apo-sGC [51, 52]. To test for sGC/apo-sGC, relaxing responses to the NO donor compound and sGC stimulator, PAPA/NO (0.01-10 μM) [53], and to the aposGC activator, BAY 60-2770 (0.01-10 μM) [51], were analyzed. Neither the PAPA/NO (
Uncoupling of endothelial NOS is considered a major cause of endothelial dysfunction characterized by decreased NO formation and increased superoxide production and occurs mainly when ROS oxidize the NOS cofactor tetrahydrobiopterin (H4Bip) [54]. When we incubated femoral arteries of aged NOX5 KI mice, pre-contracted with phenylephrine, with the H4Bip precursor sepiapterin (100 μM), Ach-induced relaxations were greatly improved and became indistinguishable from those in WT (
We also tested whether the impaired Ach-induced relaxation in femoral arteries of NOX5KI mice could be reversed by adding antioxidants to the bath medium. Neither 10 μM N-acetylcysteine nor 100 μM tempol, however, were effective (
In summary, based on human genetic, human clinical, and genetic preclinical mechanistic validation, we here report the first identified causal molecular mechanism of human systolic hypertension associated with ageing. This endotype affects approximately one in four patients and molecularly consists of a NOX5-induced uncoupling of endothelial NO synthase followed by an impaired endothelium-dependent vasodilation in muscular conduit arteries. Detection of elevated levels of NOX5 in circulating microparticles appears to serve as a mechanism-based liquid biopsy marker to stratify patients for therapeutic intervention. Based on our in vivo validation such an intervention may include the H4Bip precursor and NOS recoupling agent, sepiapterin and a NOX5 inhibitor [55-58].
Here we used a KI mouse model which expresses human NOX5 in endothelial cells and white blood cells mimicking, to a large extent, the physiological pattern of NOX5 expression in humans [31]. Expression of human NOX5 in mice led with ageing to severe systolic hypertension. This was not due to stiffening, structural remodelling or increased sensitivity to vasoconstrictor stimuli in the systemic arterial tree. It rather resulted from a regionally selective and specific attenuation of NO-mediated endothelium-dependent relaxation in medium-sized muscular conduit arteries via uncoupling of NOS.
Collectively, our data warrant clinical proof-of-concept trials aiming at a theragnostic [59] strategy in carefully stratified hypertensive patients based on the detection of elevated NOX5, ROS overproduction, e.g. by oxidatively modified proteins, and mechanism-based functional repair by a network pharmacology approach that inhibits NOX5 and recouples NOS. This is the first case of a molecular redefinition of the phenotypic disease definition, essential primary hypertension, and a first step towards precision medicine in a currently high number-needed-to-treat indication. This may be the case for about a fourth of all hypertensives.
The fact that NOX5 is also involved in a worse outcome in stroke [31], for which hypertension is a major risk factor [60], and correlates with atherosclerosis [61], this approach may not only lower blood pressure, but also two major consequences of hypertension, stroke and myocardial infarction.
On a broader scale, our present three-fold interactome-based approach for disease module discovery, pre-clinical and clinical validation appears to be applicable to a wide range of common or complex diseases. We here identify NOX5 as the missing link between ROS and impaired NO signalling. The full module consists of NOX5, NOS3, the different subunits of the NO receptor sGC and the phosphodiesterases, PDE5 and PDE9, as well as the cGMP dependent protein kinase, PKG1. Dysregulation of such a module may be best treated by multiple drugs targeting different protein components. In the present case, the WT mice mimic pharmacological NOX5 inhibition and the treatment with sepiapterin, NOS recoupling.
Disease module construction is a young research field at the interface of biomedicine and bioinformatics. We began with a seed gene-based approach, based on clinically validated proteins. NOX were suggested by GWAS in old [5] but not in younger patients [62] and are the only known enzyme family solely dedicated to ROS formation [63]. The NO-cGMP pathway is important for blood pressure regulation and its dysfunction a hallmark of hypertension[64]. Our approach yielded a module containing a sufficient set of NO-cGMP signalling components and, importantly, with Nox5 as sole ROS source. We confirmed our findings independently by two complementing in-silico network module detection approaches.
Endothelial microparticles are well established surrogate biomarkers associated with hypertension and its progression [65, 66]. They produce ROS, contain NOX, induce endothelial dysfunction and impair endothelium-dependent relaxation [67]. In human endothelial cells, angiotensin II, the target of clinically used angiotensin type 1 receptor blockers and angiotensin converting enzyme inhibitors, and the pro-hypertensive autacoid, endothelin-1, increase NOX5 expression (gene and protein) and activity [68]. In addition to its physiological vascular expression in endothelial cells, NOX5 is also increased (gene, protein, and activity) to higher levels in human renal proximal tubule cells of hypertensive patients [69], which may contribute to the observed correlation of NOX5, blood pressure and microalbuminuria. Induction of NOX5 in smooth muscle cells does not cause hypertension per se, but correlates with advanced atherosclerotic lesions and diseased coronary arteries show high NOX5 expression and activity [61]. Hypertension is rather an umbrella term for different blood pressure-elevating mechanisms. Some of these may be related to worse clinical outcome, some not. NOX5-dependent hypertension, however, appears to be disease-relevant as this molecular mechanism also leads to or aggravates hypertension-associated clinical outcomes, stroke [31], myocardial infarction [70] and renal failure [69, 71].
GWAS had delivered two NOX candidate genes, Nox4 and Nox5. Knocking out Nox4 is without a blood pressure phenotype [9, 72]; in many models, Nox4 was rather vaso-protective [10, 73, 74]. The enzymatic product of NOX4, H2O2, activates NOS [75] and is an alternative endothelium-derived relaxing factor in its own right [76-78]. This left Nox5 as candidate gene, which was confirmed by first neighbour analysis linked to NO-cGMP signalling. Unlike NOX4, NOX5 produces superoxide which can uncouple endothelial NO synthase in hypertension by oxidation of H4Bip [79, 80] in a sepiapterin-reversible manner [81]. The mechanistic validation of this role of NOX5 in hypertension was performed in a pre-clinical mouse KI model expressing NOX5, not present in the mouse genome, in the physiological cell type, endothelial cells where NOX5 is important for endothelial migration and angiogenesis [82]. In mice expressing NOX5 non-physiologically in smooth muscle cells, blood pressure is normal and angiotensin II-induced pressure effects are not augmented [14]. Of particular interest is the regionally selective effect of NOX5, which was reminiscent of the vascular heterogeneity in age-related endothelial dysfunction [83, 84]. It was present in muscular femoral conduit arteries but not in the small resistance-sized saphenous arteries of the KI mice and could, thus, selectively result in systolic hypertension with accompanying elevation of arterial pulse pressure. This effect was not reversed in our ex vivo experiments by antioxidants, presumably because NOS uncoupling was already established chronically in vivo by NOX5-derived superoxide. Preclinically, sepiapterin or H4Bip lower elevated blood pressure induced by NOS uncoupling [85, 86].
With respect to the clinical dimension of our findings, our observation that plasma ADMA levels were elevated in hypertensive patients speaks in favour of NOS uncoupling [29, 30]; yet a similar mechanistic link to NOX5 as we obtained pre-clinically in NOX5 KI mice would require the ex-vivo analysis of isolated human blood vessels or an interventional trial with sepiapterin. Indeed, sepiapterin analogues, i.e. folic acid and H4Bip, are clinically effective to reduce elevated blood pressure by improving endothelial function [88, 89]. Folic acid, either alone [90] or in combination with anti-hypertensives [91, 92], reduces the risk of cardiovascular and cerebrovascular events in hypertensive patients.
Overall, our findings using in-silico network approaches as well as further clinical and preclinical validation explain the long-observed correlation between oxidative stress, endothelial dysfunction and systolic hypertension. Humanized endothelial cell NOX5 KI mice represent the first mechanism-based animal model of human age-related hypertension and endothelial dysfunction. Therapeutically, NOX5 inhibition and NOS recoupling, ideally in combination with mechanistic biomarker stratification, e.g. based on endothelial microparticle liquid biopsies, represents a first-in-class mechanism-based approach for curative antihypertensive therapy obviating the need for symptomatic vasodilators.
In summary, hypertension is the most important cause of death and disability in the elderly. In nine of ten cases the molecular cause, however, remained unknown until now. This group is usually referred to as primary arterial hypertension.
We herein identify the mechanism behind at least a large fraction of the primary arterial hypertension cases, which were until now considered as treatment-resistant hypertension.
We identified this mechanism to involve impaired endothelium-dependent vasodilation through reactive oxygen (ROS) species. We found that ROS forming Nox genes associate with hypertension and we herein identify Nox5, not present in rodents, as sole neighbour to human vasodilatory endothelial nitric oxide (NO) signalling.
We found that in hypertensive subjects, endothelial microparticles contained higher levels of NOX5 with a bimodal distribution correlating with disease severity.
It appeared that the subjects with a high level of circulating NOX5 levels could effectively be treated with NOX5 inhibitors or with a compound selected from the group consisting of sepiapterin, L-citrulline, L-arginine, tetrahydrobiopterin and folic acid. An example of a suitable NOX5 inhibitor is ML090. Further examples of suitable NOX5 inhibitors are for example perphenazine, ML171, GKT-831 and VAS2870.
We found that mice expressing human NOX5 in endothelial cells, developed upon aging, severe systolic hypertension and impaired endothelium-dependent vasodilation due to uncoupled NO synthase. We conclude that NOX5-induced uncoupling of endothelial NO synthase is a causal mechanism and theragnostic target of an age-related hypertension endotype. We conclude that Nox5 knock-in mice represent the first mechanism-based animal model of hypertension.
In one embodiment, the invention therefore relates to a novel method for diagnosing essential arterial hypertension in a subject wherein the level of NADPH oxidase 5 (NOX5) is determined in a fluid or tissue sample from the subject, and wherein it is concluded that the subject has essential arterial hypertension if the level of NOX5 is above a predetermined threshold level. This method identifies the subjects with a disease entity that was previously called treatment-resistant hypertension. Those cases may now effectively be treated with NOX5 inhibitors or with compounds selected from the group consisting of sepiapterin, L-citrulline, L-arginine, tetrahydrobiopterin and folic acid. Those cases may now effectively be treated with NOX5 inhibitor setanaxib (2-(2-Chloropheny)-4-[3-(di-methylamino)phenyl]-5-methyl-1H-pyrazolo[4,3-c]pyridine-3,6-dione), ML171, VAS2870, perphenazine or ML090 (5,12-dihydroquinoxalino(2,3-B)quinoxaline), with molecular structure (1):
In one embodiment, the invention therefore relates to a novel method for diagnosing a hypertension endotype in a subject wherein the level of NOX5 is determined in a fluid or tissue sample from the subject, preferably plasma sample, and wherein it is concluded that the subject has the hypertension endotype if the level of NOX5 is above a predetermined threshold level. The threshold level can be defined as the amount of NOX5 protein (enzyme) per volume, such as pg NOX5 per ml plasma of the hypertension endotype patient. The threshold level can also be defined as the NOX5 enzyme activity per volume, such as I.U. enzyme activity per ml plasma of the patient suffering from the endotype. This method identifies the subjects with a disease entity (endotype) that was previously a disease entity generally called treatment-resistant hypertension. Those cases of resistant hypertension patients suffering from the endotype as now defined by the inventors may now effectively be treated with NOX5 inhibitors or with compounds selected from the group consisting of sepiapterin, L-citrulline, L-arginine, tetrahydrobiopterin and folic acid. Those cases may now effectively be treated with NOX5 inhibitor setanaxib (2-(2-Chloropheny)-4-[3-(di-methylamino)phenyl]-5-methyl-1H-pyrazolo[4,3-c]pyridine-3,6-dione), ML171, VAS2870, perphenazine or ML090 (5,12-dihydroquinoxalino(2,3-B)quinoxaline), with molecular structure (1):
Further NOX5 inhibitors suitable for inhibiting NOX5 in the patients suffering from the NOX5-dependent hypertension are for example anti-human NOX5 antibodies, or any binding domain(s) thereof or any binding fragment(s) thereof endowed with the ability to inhibit NOX5 enzyme activity, or an siRNA suitable for gene silencing of the human Nox5 gene.
An aspect of the invention relates to a method for detection of a hypertension endotype (NOX5-dependent hypertension) in a human patient suffering from essential arterial hypertension, wherein said endotype is defined by an increased level of circulating NADPH oxidase 5 protein (NOX5) compared to the level of circulating NOX5 in a human patient not suffering from hypertension, the method comprising the steps of:
-
- (a) obtaining a fluid sample from the human patient who suffers from essential arterial hypertension, selected from the group comprising plasma, blood and serum, wherein the fluid sample comprises circulating endothelial microparticles;
- (b) isolating the endothelial microparticles from the fluid sample provided in step (a); and
- (c) measuring NOX5 in the endothelial microparticles of step (b) using a protein detection assay and determining the concentration of NOX5 in the fluid sample in pg NOX5 per ml fluid sample,
wherein it is concluded that the human patient suffers from the hypertension endotype (NOX5-dependent hypertension) if the concentration of NOX5 as determined in step (c) is at least 160 pg NOX5 per ml of the fluid sample. The threshold level can also be defined as the NOX5 enzyme activity per volume, such as I.U. enzyme activity per ml plasma of the patient suffering from the endotype.
Preferred is the method for detection of the hypertension endotype (NOX5-dependent hypertension) in a human patient suffering from essential arterial hypertension, wherein the fluid sample is a plasma sample.
The invention also relates to a method for detection of a hypertension endotype (NOX5-dependent hypertension) in a human patient suffering from essential arterial hypertension, wherein said endotype is defined by an increased level of circulating NADPH oxidase 5 protein (NOX5) compared to the level of circulating NOX5 in a human subject not suffering from hypertension, the method comprising the steps of:
-
- (a) obtaining a plasma sample from the human patient who suffers from essential arterial hypertension; and
- (b) measuring NOX5 in the plasma sample of step (a) using a protein detection assay and determining the concentration of NOX5 in the plasma sample in pg NOX5 per ml plasma,
wherein it is concluded that the human patient suffers from the hypertension endotype (NOX5-dependent hypertension) if the concentration of NOX5 as determined in step (b) is at least 160 pg NOX5 per ml of the plasma sample.
Particularly, in the method for detection of the hypertension endotype (NOX5-dependent hypertension) in a human patient suffering from essential arterial hypertension, the human patient suffers from hypertension as defined as a systolic blood pressure of at least 140 mmHg, a diastolic blood pressure of at least 90 mmHg, or use of an antihypertensive drug. More in particular, in the method for detection of the hypertension endotype in a human patient suffering from essential arterial hypertension, the human patient suffers from hypertension as defined as a systolic blood pressure of at least 135 mmHg, a diastolic blood pressure of at least 85 mmHg, or use of an antihypertensive drug, in the absence of diabetes and in the absence of other risk factors for myocardial infarction and stroke. Even more in particular, in the method for detection of the hypertension endotype in a human patient suffering from essential arterial hypertension, the human patient suffers from resistant hypertension according to the definition as provided by the American Heart Association [104] as: above-goal elevated blood pressure (BP) in a patient despite the concurrent use of three anti-hypertensive drug classes, commonly including a long-acting calcium channel blocker, a blocker of the renin-angiotensin system (angiotensin-converting enzyme inhibitor or angiotensin receptor blocker), and a diuretic. The antihypertensive drugs should be administered at maximum or maximally tolerated daily doses. RH also includes patients whose BP achieves target values on more than four anti-hypertensive medications. The diagnosis of RH requires assurance of anti-hypertensive medication adherence and exclusion of the “white-coat effect” (office BP above goal but out-of-office BP at or below target).
For the method for detection of the hypertension endotype (NOX5-dependent hypertension) in a human patient suffering from essential arterial hypertension, the human patient does not have a history or clinical evidence of any of: angina, myocardial infarction, congestive heart failure, peripheral vascular disease, inflammatory disease and any disease predisposing to vasculitis, and wherein the human patient does not have stage 4 or stage 5 chronic kidney disease.
An embodiment is the method for the detection of a hypertension endotype (NOX5-dependent hypertension) in a human patient suffering from essential arterial hypertension, wherein in step (c) the protein detection assay is an enzyme-linked immunosorbent assay.
An aspect of the invention relates to a method for the detection of a hypertension endotype (NOX5-dependent hypertension) in a human patient suffering from essential arterial hypertension, wherein said endotype is hypertension characterized by being
-
- accompanied by renal vascular leakage as established by the occurrence of microalbuminuria; or
- associated with the risk for developing renal vascular leakage apparent as development of microalbuminuria,
the method comprising the steps of - (a) obtaining a fluid sample from the human patient who suffers from essential arterial hypertension, selected from the group comprising plasma, blood and serum, wherein the fluid sample comprises circulating endothelial microparticles;
- (b) isolating the endothelial microparticles from the fluid sample provided in step (a); and
- (c) measuring NADPH oxidase 5 protein (NOX5) in the endothelial microparticles of step (b) using a protein detection assay and determining the concentration of NOX5 in the fluid sample in pg NOX5 per ml fluid sample,
wherein it is concluded that the human patient has the hypertension endotype (NOX5-dependent hypertension) if the concentration of NOX5 is at least 160 pg NOX5 per ml of the fluid sample. The threshold level can also be defined as the NOX5 enzyme activity per volume, such as I.U. enzyme activity per ml plasma of the patient suffering from the endotype.
For the method for the detection of a hypertension endotype (NOX5-dependent hypertension) in a human patient suffering from essential arterial hypertension, the human patient typically has a systolic arterial blood pressure of at least 140 mmHg and a diastolic arterial blood pressure of at least 90 mmHg at two days. More in particular, for the method for the detection of a hypertension endotype (NOX5-dependent hypertension) in a human patient suffering from essential arterial hypertension, the human patient typically has a systolic arterial blood pressure of at least 135 mmHg and a diastolic arterial blood pressure of at least 85 mmHg, in the absence of diabetes and in the absence of other risk factors for myocardial infarction and stroke. Even more in particular, the method is for the detection of the hypertension endotype (NOX5-dependent hypertension) in patients suffering from resistant hypertension. The resistant hypertension (RH) can be defined according to the definition as provided by the American Heart Association [104] as: above-goal elevated blood pressure (BP) in a patient despite the concurrent use of three anti-hypertensive drug classes, commonly including a long-acting calcium channel blocker, a blocker of the renin-angiotensin system (angiotensin-converting enzyme inhibitor or angiotensin receptor blocker), and a diuretic. The antihypertensive drugs should be administered at maximum or maximally tolerated daily doses. RH also includes patients whose BP achieves target values on more than four anti-hypertensive medications. The diagnosis of RH requires assurance of anti-hypertensive medication adherence and exclusion of the “white-coat effect” (office BP above goal but out-of-office BP at or below target).
An embodiment is the method for the detection of al hypertension endotype (NOX5-dependent hypertension) in a human patient suffering from essential arterial hypertension, wherein in step (a) the fluid sample is a plasma sample.
An embodiment is the method for the detection of a hypertension endotype (NOX5-dependent hypertension) in a human patient suffering from essential arterial hypertension, wherein in step (c) the protein detection assay is an enzyme-linked immunosorbent assay.
An aspect of the invention relates to a method for diagnosing occurrence of a hypertension endotype (NOX5-dependent hypertension) in a human patient suffering from essential arterial hypertension, wherein said endotype is hypertension characterized by being
-
- accompanied by renal vascular leakage as established by the occurrence of micro-albuminuria; or
- associated with the risk for developing renal vascular leakage apparent as development of micro-albuminuria,
the method comprising the steps of: - (a) obtaining a fluid sample from the human patient who suffers from essential arterial hypertension, selected from the group comprising plasma, blood and serum, wherein the fluid sample comprises endothelial microparticles;
- (b) isolating the endothelial microparticles from the fluid sample provided in step (a); and
- (c) measuring NADPH oxidase 5 protein (NOX5) in the endothelial microparticles of step (b) using a protein detection assay and determining the concentration of NOX5 in the fluid sample in pg NOX5 per ml fluid sample,
wherein it is concluded that the human patient has the hypertension endotype (NOX5-dependent hypertension) if the concentration of NOX5 is at least 160 pg NOX5 per ml of the fluid sample. The threshold level can also be defined as the NOX5 enzyme activity per volume, such as I.U. enzyme activity per ml plasma of the patient suffering from the endotype (NOX5-dependent hypertension).
Typically, the endothelial microparticles are circulating endothelial microparticles.
An aspect of the invention relates to a method of diagnosing nicotinamide adenine dinucleotide phosphate (NAPDH) oxidase 5 (NOX5)-dependent hypertension in a patient by testing for the presence of an NOX5 concentration of at least 160 pg per ml in a plasma sample obtained from the patient who suffers from essential arterial hypertension. The threshold level can also be defined as the NOX5 enzyme activity per volume, such as I.U. enzyme activity per ml plasma of the patient suffering from the endotype.
An aspect of the invention relates to a method of diagnosing NOX5-dependent hypertension in a patient, comprising determining the level of NOX5 in a fluid or tissue sample from the patient, and wherein it is concluded that the patient has NOX5-dependent hypertension if the level of NOX5 is above 160 pg per ml. The threshold level can also be defined as the NOX5 enzyme activity per volume, such as I.U. enzyme activity per ml plasma of the patient suffering from the endotype (NOX5-dependent hypertension).
An embodiment is the method of diagnosing NOX5-dependent hypertension in a patient, wherein the fluid or tissue sample is a plasma sample.
An embodiment is the method of diagnosing NOX5-dependent hypertension in a patient comprising the steps of:
-
- (a) isolating endothelial microparticles from the plasma sample; and
- (b) measuring NOX5 in the endothelial microparticles of step (a) using a protein detection assay and determining the concentration of NOX5 in the plasma sample in pg NOX5 per ml plasma sample,
wherein the human patient is diagnosed as suffering from NOX5-dependent hypertension if the concentration of NOX5 as determined in step (b) is at least 160 pg NOX5 per ml of the plasma sample. The threshold level can also be defined as the NOX5 enzyme activity per volume, such as I.U. enzyme activity per ml plasma of the patient suffering from the endotype.
Preferably, the endothelial microparticles are circulating endothelial microparticles.
An aspect of the invention relates to a method for diagnosing occurrence of a hypertension endotype (NOX5-dependent hypertension) in a human patient suffering from essential arterial hypertension, wherein said endotype is defined by an increased level of circulating NADPH oxidase 5 protein (NOX5) compared to the level of circulating NOX5 in a human patient not suffering from hypertension,
the method comprising the steps of:
-
- (a) obtaining a fluid sample from the human patient who suffers from essential arterial hypertension, selected from the group comprising plasma, blood and serum, wherein the fluid sample comprises endothelial microparticles;
- (b) isolating the endothelial microparticles from the fluid sample provided in step (a); and
- (c) measuring NOX5 in the endothelial microparticles of step (b) using a protein detection assay and determining the concentration of NOX5 in the fluid sample in pg NOX5 per ml fluid sample,
wherein it is concluded that the human patient suffers from the hypertension endotype (NOX5-dependent hypertension) if the concentration of NOX5 as determined in step (c) is at least 160 pg NOX5 per ml of the fluid sample. The threshold level can also be defined as the NOX5 enzyme activity per volume, such as I.U. enzyme activity per ml plasma of the patient suffering from the endotype.
Typically, the endothelial microparticles are circulating endothelial microparticles.
An embodiment is the method for diagnosing occurrence of a hypertension endotype (NOX5-dependent hypertension) in a human patient suffering from essential arterial hypertension, wherein the fluid sample obtained from the human patient in step (a) is a plasma sample.
An embodiment is the method for diagnosing occurrence of a hypertension endotype (NOX5-dependent hypertension) in a human patient suffering from essential arterial hypertension, wherein the human patient suffers from hypertension as defined as a systolic blood pressure of at least 140 mmHg, a diastolic blood pressure of at least 90 mmHg, or use of an antihypertensive drug. An embodiment is the method for diagnosing occurrence of a hypertension endotype (NOX5-dependent hypertension) in a human patient suffering from essential arterial hypertension, wherein the human patient suffers from hypertension as defined as a systolic blood pressure of at least 135 mmHg, a diastolic blood pressure of at least 85 mmHg, or use of an antihypertensive drug.
An embodiment is the method for diagnosing occurrence of a hypertension endotype (NOX5-dependent hypertension) in a human patient suffering from essential arterial hypertension, wherein the human patient does not have a history or clinical evidence of any of: angina, myocardial infarction, congestive heart failure, peripheral vascular disease, inflammatory disease and any disease predisposing to vasculitis, and wherein the human patient does not have stage 4 or stage 5 chronic kidney disease.
An aspect of the invention relates to a method for treating NADPH oxidase 5 (NOX5)-dependent hypertension comprising administering one or more of the compounds sepiapterin, folic acid, L-citrulline, L-arginine and tetrahydrobiopterin to a human patient suffering from essential arterial hypertension, wherein the human patient has an NOX5 plasma concentration of at least 160 pg NOX5 per ml plasma.
An aspect of the invention relates to a method for treating NOX5-dependent hypertension comprising administering sepiapterin to a human patient suffering from essential arterial hypertension, wherein the human patient has an NOX5 plasma concentration of at least 160 pg NOX5 per ml plasma. The threshold level can also be defined as the NOX5 enzyme activity per volume, such as I.U. enzyme activity per ml plasma of the patient suffering from the endotype.
Also preferred is the method for treating NOX5-dependent hypertension, wherein the human patient has moderately increased albuminuria defined as albumin excretion rate of 20-200 mg per minute.
For some embodiments, for the method for treating NOX5-dependent hypertension, the human patient is diagnosed as suffering from NOX5-dependent hypertension with the method of detection of NOX5-dependent hypertension or the method of diagnosing of NOX5-dependent hypertension as herein described.
An embodiment is the method for treating NOX5-dependent hypertension, wherein the human patient is at least 53 years of age.
An embodiment is the method for treating NOX5-dependent hypertension, wherein the human patient is at least 57 years of age. Typically, the patient may also suffer from micro-albuminuria.
An embodiment is the method for treating NOX5-dependent hypertension, wherein the human patient has a plasma concentration of asymmetric dimethylarginine (ADMA) that is higher compared to the average plasma concentration of asymmetric dimethylarginine of a group of healthy human patients.
An embodiment is the method for treating NOX5-dependent hypertension, wherein the human patient has a plasma concentration of asymmetric dimethylarginine of at least 0.53 micromol per liter, preferably at least 0.58 micromol per liter, more preferably at least 0.63 micromol per liter.
An embodiment is the method for treating NOX5-dependent hypertension, wherein the human patient suffers from hypertension as defined as a systolic blood pressure of at least 140 mmHg, a diastolic blood pressure of at least 90 mmHg, or use of an antihypertensive drug. An embodiment is the method for treating NOX5-dependent hypertension, wherein the human patient suffers from hypertension as defined as a systolic blood pressure of at least 135 mmHg, a diastolic blood pressure of at least 85 mmHg, or use of an antihypertensive drug.
In embodiments, in the method for treating NOX5-dependent hypertension, the human patient does not have a history or clinical evidence of any of: angina, myocardial infarction, congestive heart failure, peripheral vascular disease, inflammatory disease and any disease predisposing to vasculitis, and wherein the human patient does not have stage 4 or stage 5 chronic kidney disease.
An aspect of the invention relates to a method for treating NOX5-dependent hypertension, the method for treating comprising administering an NOX5 inhibitor to a human patient suffering from essential arterial hypertension. Typically, the method comprises administering an NOX5 inhibitor to a human patient suffering from essential arterial hypertension, wherein the human patient has an NOX5 plasma concentration of at least 160 pg NOX5 per ml plasma. The threshold level can also be defined as the NOX5 enzyme activity per volume, such as I.U. enzyme activity per ml plasma of the patient suffering from the endotype.
An aspect of the invention relates to a method for treating NOX5-dependent hypertension, the method for treating comprising administering the NOX5 inhibitor 5,12-dihydroquinoxalino(2,3-B)quinoxaline (ML090) to a human patient suffering from essential arterial hypertension. Typically, the method comprises administering ML090 to a human patient suffering from essential arterial hypertension, wherein the human patient has an NOX5 plasma concentration of at least 160 pg NOX5 per ml plasma. The threshold level can also be defined as the NOX5 enzyme activity per volume, such as I.U. enzyme activity per ml plasma of the patient suffering from the endotype (NOX5-dependent hypertension).
The invention further relates to a compound selected from the group consisting of sepiapterin, L-citrulline, L-arginine, tetrahydrobiopterin, folic acid and a NOX5 inhibitor, in particular a NOX5 inhibitor based on quinoxaline such as NOX5 inhibitor 5,12-dihydroquinoxalino(2,3-B)quinoxaline (ML090), for use in the treatment of a subject with essential arterial hypertension, in particular with NOX5-dependent hypertension. Another suitable NOX5 inhibitor is setanaxib (2-(2-Chloropheny)-4-[3-(di-methylamino)phenyl]-5-methyl-1H-pyrazolo[4,3-c]pyridine-3,6-dione). Further NOX5 inhibitors suitable for inhibiting NOX5 in the patients suffering from the hypertension endotype (NOX5-dependent hypertension) are for example anti-human NOX5 antibodies, or any binding domain(s) thereof or any binding fragment(s) thereof endowed with the ability to inhibit NOX5 enzyme activity, or an siRNA suitable for gene silencing of the human Nox5 gene. In addition, NOX5 inhibitors suitable for inhibiting NOX5 in the patients suffering from the NOX5-dependent hypertension are for example perphenazine, ML171 and VAS2870.
An embodiment is the method for treating NOX5-dependent hypertension comprising administering an NOX5 inhibitor, such as a NOX5 inhibitor based on quinoxaline such as ML090, wherein the human patient has moderately increased albuminuria defined as albumin excretion rate of 20-200 mg per minute.
An embodiment is the method for treating NOX5-dependent hypertension comprising administering an NOX5 inhibitor, such as a NOX5 inhibitor based on quinoxaline such as ML090, wherein the human patient is diagnosed as suffering from NOX5-dependent hypertension with the method of detecting NOX5-dependent hypertension, or with the method of diagnosing NOX5-dependent hypertension. Another suitable NOX5 inhibitor is setanaxib (2-(2-Chloropheny)-4-[3-(di-methylamino)phenyl]-5-methyl-1H-pyrazolo[4,3-c]pyridine-3,6-dione). Further NOX5 inhibitors suitable for inhibiting NOX5 in the patients suffering from the hypertension endotype (NOX5-dependent hypertension) are for example anti-human NOX5 antibodies, or any binding domain(s) thereof or any binding fragment(s) thereof endowed with the ability to inhibit NOX5 enzyme activity, or an siRNA suitable for gene silencing of the human Nox5 gene. In addition, NOX5 inhibitors suitable for inhibiting NOX5 in the patients suffering from the NOX5-dependent hypertension are for example perphenazine, ML171 and VAS2870.
An embodiment is the method for treating NOX5-dependent hypertension comprising administering an NOX5 inhibitor, such as a NOX5 inhibitor based on quinoxaline such as ML090, wherein the human patient is at least 53 years of age.
An embodiment is the method for treating NOX5-dependent hypertension comprising administering an NOX5 inhibitor, such as ML090, wherein the human patient is at least 57 years of age. In embodiments, the patient has micro-albuminuria. Another suitable NOX5 inhibitor is setanaxib (2-(2-Chloropheny)-4-[3-(di-methylamino)phenyl]-5-methyl-1H-pyrazolo[4,3-c]pyridine-3,6-dione). Further NOX5 inhibitors suitable for inhibiting NOX5 in the patients suffering from the hypertension endotype (NOX5-dependent hypertension) are for example anti-human NOX5 antibodies, or any binding domain(s) thereof or any binding fragment(s) thereof endowed with the ability to inhibit NOX5 enzyme activity, or an siRNA suitable for gene silencing of the human Nox5 gene. In addition, NOX5 inhibitors suitable for inhibiting NOX5 in the patients suffering from the NOX5-dependent hypertension are for example perphenazine, ML171 and VAS2870.
An embodiment is the method for treating NOX5-dependent hypertension comprising administering an NOX5 inhibitor, such as a NOX5 inhibitor based on quinoxaline such as ML090, wherein the human patient has a plasma concentration of asymmetric dimethylarginine that is higher compared to the average plasma concentration of asymmetric dimethylarginine of a group of healthy human patients. Another suitable NOX5 inhibitor is setanaxib (2-(2-Chloropheny)-4-[3-(di-methylamino)phenyl]-5-methyl-1H-pyrazolo[4,3-c]pyridine-3,6-dione). Further NOX5 inhibitors suitable for inhibiting NOX5 in the patients suffering from the hypertension endotype (NOX5-dependent hypertension) are for example anti-human NOX5 antibodies, or any binding domain(s) thereof or any binding fragment(s) thereof endowed with the ability to inhibit NOX5 enzyme activity, or an siRNA suitable for gene silencing of the human Nox5 gene. In addition, NOX5 inhibitors suitable for inhibiting NOX5 in the patients suffering from the NOX5-dependent hypertension are for example perphenazine, ML171 and VAS2870.
An embodiment is the method for treating NOX5-dependent hypertension comprising administering an NOX5 inhibitor, such as a NOX5 inhibitor based on quinoxaline such as ML090, wherein the human patient has a plasma concentration of asymmetric dimethylarginine of at least 0.53 micromol per liter, preferably at least 0.58 micromol per liter, more preferably at least 0.63 micromol per liter. Another suitable NOX5 inhibitor is setanaxib (2-(2-Chloropheny)-4-[3-(di-methylamino)phenyl]-5-methyl-1H-pyrazolo[4,3-c]pyridine-3,6-dione). Further NOX5 inhibitors suitable for inhibiting NOX5 in the patients suffering from the hypertension endotype (NOX5-dependent hypertension) are for example anti-human NOX5 antibodies, or any binding domain(s) thereof or any binding fragment(s) thereof endowed with the ability to inhibit NOX5 enzyme activity, or an siRNA suitable for gene silencing of the human Nox5 gene. In addition, NOX5 inhibitors suitable for inhibiting NOX5 in the patients suffering from the NOX5-dependent hypertension are for example perphenazine, ML171 and VAS2870.
An embodiment is the method for treating NOX5-dependent hypertension comprising administering an NOX5 inhibitor, such as a NOX5 inhibitor based on quinoxaline such as ML090, wherein the human patient suffers from hypertension as defined as a systolic blood pressure of at least 140 mmHg, a diastolic blood pressure of at least 90 mmHg, or use of an antihypertensive drug.
An embodiment is the method for treating NOX5-dependent hypertension comprising administering an NOX5 inhibitor, such as ML090, wherein the human patient suffers from hypertension as defined as a systolic blood pressure of at least 135 mmHg, a diastolic blood pressure of at least 85 mmHg, or use of an antihypertensive drug. Another suitable NOX5 inhibitor is setanaxib (2-(2-Chloropheny)-4-[3-(di-methylamino)phenyl]-5-methyl-1H-pyrazolo[4,3-c]pyridine-3,6-dione). Further NOX5 inhibitors suitable for inhibiting NOX5 in the patients suffering from the hypertension endotype (NOX5-dependent hypertension) are for example anti-human NOX5 antibodies, or any binding domain(s) thereof or any binding fragment(s) thereof endowed with the ability to inhibit NOX5 enzyme activity, or an siRNA suitable for gene silencing of the human Nox5 gene. In addition, NOX5 inhibitors suitable for inhibiting NOX5 in the patients suffering from the NOX5-dependent hypertension are for example perphenazine, ML171 and VAS2870.
An embodiment is the method for treating NOX5-dependent hypertension comprising administering an NOX5 inhibitor, such as a NOX5 inhibitor based on quinoxaline such as ML090, wherein the human patient does not have a history or clinical evidence of any of: angina, myocardial infarction, congestive heart failure, peripheral vascular disease, inflammatory disease and any disease predisposing to vasculitis, and wherein the human patient does not have stage 4 or stage 5 chronic kidney disease. Another suitable NOX5 inhibitor is setanaxib (2-(2-Chloropheny)-4-[3-(di-methylamino)phenyl]-5-methyl-1H-pyrazolo[4,3-c]pyridine-3,6-dione). Further NOX5 inhibitors suitable for inhibiting NOX5 in the patients suffering from the hypertension endotype (NOX5-dependent hypertension) are for example anti-human NOX5 antibodies, or any binding domain(s) thereof or any binding fragment(s) thereof endowed with the ability to inhibit NOX5 enzyme activity, or an siRNA suitable for gene silencing of the human Nox5 gene. In addition, NOX5 inhibitors suitable for inhibiting NOX5 in the patients suffering from the NOX5-dependent hypertension are for example perphenazine, ML171 and VAS2870.
An aspect of the invention relates to administering an effective amount of one or more of sepiapterin, folic acid, L-citrulline, L-arginine and tetrahydrobiopterin to a human patient to treat NADPH oxidase 5 (NOX5)-dependent hypertension.
An embodiment is the administering of an effective amount of one or more sepiapterin, folic acid, L-citrulline, L-arginine and tetrahydrobiopterin to a human patient to treat NOX5-dependent hypertension, wherein the human patient has an NOX5 plasma concentration of at least 160 pg NOX5 per ml plasma. The threshold level can also be defined as the NOX5 enzyme activity per volume, such as I.U. enzyme activity per ml plasma of the patient suffering from the endotype (NOX5-dependent hypertension).
An embodiment is the administering of an effective amount of sepiapterin to a human patient to treat NOX5-dependent hypertension, preferably wherein the human patient has an NOX5 plasma concentration of at least 160 pg NOX5 per ml plasma. The threshold level can also be defined as the NOX5 enzyme activity per volume, such as I.U. enzyme activity per ml plasma of the patient suffering from the endotype (NOX5-dependent hypertension).
An embodiment is the administering of an effective amount of one or more sepiapterin, folic acid, L-citrulline, L-arginine and tetrahydrobiopterin to a human patient to treat NOX5-dependent hypertension, wherein said human patient is diagnosed as suffering from NOX5-dependent hypertension with the method of the detection of a hypertension endotype (NOX5-dependent hypertension) in a human patient suffering from essential arterial hypertension.
An aspect of the invention relates to administering an effective amount of an NOX5 inhibitor to a human patient to treat NADPH oxidase 5 (NOX5)-dependent hypertension.
An aspect of the invention relates to administering an effective amount of a NOX5 inhibitor based on a quinoxaline to a human patient to treat NADPH oxidase 5 (NOX5)-dependent hypertension.
An aspect of the invention relates to administering an effective amount of NOX5 inhibitor 5,12-dihydroquinoxalino(2,3-B)quinoxaline (ML090) to a human patient to treat NADPH oxidase 5 (NOX5)-dependent hypertension.
An aspect of the invention relates to administering an effective amount of NOX5 inhibitor setanaxib (2-(2-Chloropheny)-4-[3-(di-methylamino)phenyl]-5-methyl-1H-pyrazolo[4,3-c]pyridine-3,6-dione) to a human patient to treat NOX5-dependent hypertension. In addition, NOX5 inhibitors suitable for inhibiting NOX5 in the patients suffering from the NOX5-dependent hypertension are for example perphenazine, ML171 and VAS2870.
An embodiment is the administering of an effective amount of an NOX5 inhibitor such as a NOX5 inhibitor based on quinoxaline such as 5,12-dihydroquinoxalino(2,3-B)quinoxaline or setanaxib (2-(2-Chloropheny)-4-[3-(di-methylamino)phenyl]-5-methyl-1H-pyrazolo[4,3-c]pyridine-3,6-dione) to a human patient to treat NOX5-dependent hypertension, wherein the human patient has an NOX5 plasma concentration of at least 160 pg NOX5 per ml plasma. Further NOX5 inhibitors suitable for inhibiting NOX5 in the patients suffering from the hypertension endotype (NOX5-dependent hypertension) are for example anti-human NOX5 antibodies, or any binding domain(s) thereof or any binding fragment(s) thereof endowed with the ability to inhibit NOX5 enzyme activity, or an siRNA suitable for gene silencing of the human Nox5 gene. In addition, NOX5 inhibitors suitable for inhibiting NOX5 in the patients suffering from the NOX5-dependent hypertension are for example perphenazine, ML171 and VAS2870. The threshold level can also be defined as the NOX5 enzyme activity per volume, such as I.U. enzyme activity per ml plasma of the patient suffering from the endotype (NOX5-dependent hypertension).
An embodiment is the administering of an effective amount of an NOX5 inhibitor or a NOX5 inhibitor based on quinoxaline such as 5,12-dihydroquinoxalino(2,3-B)quinoxaline or setanaxib (2-(2-Chlorophenyl)-4-[3-(di-methylamino)phenyl]-5-methyl-1H-pyrazolo[4,3-c]pyridine-3,6-dione) to a human patient to treat NOX5-dependent hypertension, wherein said human patient is diagnosed as suffering from NOX5-dependent hypertension with the method for diagnosing occurrence of a hypertension endotype (NOX5-dependent hypertension) in a human patient suffering from essential arterial hypertension. In addition, NOX5 inhibitors suitable for inhibiting NOX5 in the patients suffering from the NOX5-dependent hypertension are for example perphenazine, ML171 and VAS2870.
An aspect of the invention relates to a method for treating NADPH oxidase 5 (NOX5)-dependent hypertension comprising administering an effective amount one or more of the compounds sepiapterin, L-arginine, L-citrulline, folic acid and tetrahydrobiopterin to a human patient suffering from essential arterial hypertension, wherein the human patient has an NOX5 plasma concentration of at least 160 pg NOX5 per ml plasma. The threshold level can also be defined as the NOX5 enzyme activity per volume, such as I.U. enzyme activity per ml plasma of the patient suffering from the endotype (NOX5-dependent hypertension).
An aspect of the invention relates to a method for treating NOX5-dependent hypertension comprising administering a compound selected from sepiapterin, folic acid, L-citrulline, L-arginine and tetrahydrobiopterin to a patient with essential arterial hypertension, characterised in that the patient with essential arterial hypertension has an NOX5 plasma concentration of at least 160 pg NOX5 per ml plasma. The threshold level can also be defined as the NOX5 enzyme activity per volume, such as I.U. enzyme activity per ml plasma of the patient suffering from the endotype (NOX5-dependent hypertension).
An embodiment is the method for treating NOX5-dependent hypertension, wherein the essential arterial hypertension is NOX5-dependent hypertension.
An aspect of the invention relates to a method for treating NOX5-dependent hypertension comprising administering a compound selected from sepiapterin, folic acid, L-citrulline, L-arginine and tetrahydrobiopterin to a patient having treatment-resistant hypertension.
An embodiment is the method for treating NOX5-dependent hypertension comprising administering a compound selected from sepiapterin, folic acid, L-citrulline, L-arginine and tetrahydrobiopterin to a patient having treatment-resistant hypertension, wherein the patient has an NOX5 plasma concentration of at least 160 pg NOX5 per ml plasma. The threshold level can also be defined as the NOX5 enzyme activity per volume, such as I.U. enzyme activity per ml plasma of the patient suffering from the endotype (NOX5-dependent hypertension).
An embodiment is the method for treating NOX5-dependent hypertension comprising administering a compound selected from sepiapterin, folic acid, L-citrulline, L-arginine and tetrahydrobiopterin to a patient having treatment-resistant hypertension, wherein the patient has an NOX5 plasma concentration of at least 160 pg NOX5 per ml plasma. The threshold level can also be defined as the NOX5 enzyme activity per volume, such as I.U. enzyme activity per ml plasma of the patient suffering from the endotype (NOX5-dependent hypertension).
An embodiment is the method for treating NOX5-dependent hypertension, wherein the compound is sepiapterin.
An embodiment is the method for treating NOX5-dependent hypertension, wherein the patient has moderately increased albuminuria defined as albumin excretion rate of 20-200 mg per minute.
An embodiment is the method for treating NOX5-dependent hypertension, wherein the patient is diagnosed as suffering from NOX5-dependent hypertension with the method of the detection or diagnosing of a hypertension endotype (NOX5-dependent hypertension) in a human patient suffering from essential arterial hypertension, the endotype characterized by a plasma level of NOX5 of at least 160 pg/ml. The threshold level can also be defined as the NOX5 enzyme activity per volume, such as I.U. enzyme activity per ml plasma of the patient suffering from the endotype (NOX5-dependent hypertension).
An embodiment is the method for treating NOX5-dependent hypertension, wherein the patient is at least 53 years of age.
An embodiment is the method for treating NOX5-dependent hypertension, wherein the patient is at least 57 years of age. Typically, the patient suffers from micro-albuminuria.
An embodiment is the method for treating NOX5-dependent hypertension, wherein the patient has a plasma concentration of asymmetric dimethylarginine that is higher compared to the average plasma concentration of asymmetric dimethylarginine of a group of healthy patients.
An embodiment is the method for treating NOX5-dependent hypertension, wherein the patient has a plasma concentration of asymmetric dimethylarginine of at least 0.53 micromol per liter, preferably at least 0.58 micromol per liter, more preferably at least 0.63 micromol per liter.
An embodiment is the method for treating NOX5-dependent hypertension or the method for the detection of the hypertension endotype (NOX5-dependent hypertension) characterized by a plasma level of NOX5 of at least 160 pg/ml in a human patient suffering from essential arterial hypertension, wherein the patient suffers from hypertension as defined as a systolic blood pressure of at least 140 mmHg, a diastolic blood pressure of at least 90 mmHg, or use of an antihypertensive drug. An embodiment is the method for treating NOX5-dependent hypertension or the method for the detection of the hypertension endotype (NOX5-dependent hypertension) characterized by a plasma level of NOX5 of at least 160 pg/ml in a human patient suffering from essential arterial hypertension, wherein the patient suffers from hypertension as defined as a systolic blood pressure of at least 135 mmHg, a diastolic blood pressure of at least 85 mmHg, or use of an antihypertensive drug. The threshold level can also be defined as the NOX5 enzyme activity per volume, such as I.U. enzyme activity per ml plasma of the patient suffering from the endotype (NOX5-dependent hypertension).
An embodiment is the method for treating NOX5-dependent hypertension or the method for the detection of the hypertension endotype (NOX5-dependent hypertension) characterized by a plasma level of NOX5 of at least 160 pg/ml in a human patient suffering from essential arterial hypertension, wherein the patient does not have a history or clinical evidence of any of: angina, myocardial infarction, congestive heart failure, peripheral vascular disease, inflammatory disease and any disease predisposing to vasculitis, and wherein the patient does not have stage 4 or stage 5 chronic kidney disease. The threshold level can also be defined as the NOX5 enzyme activity per volume, such as I.U. enzyme activity per ml plasma of the patient suffering from the endotype (NOX5-dependent hypertension).
An aspect of the invention relates to the use of a mouse with knocked-in human Nox5 gene to discover and develop therapeutics and methods for detection, for the use in NOX5-dependent hypertension in a patient.
An embodiment is the use of a mouse with knocked-in human Nox5 gene, wherein the mouse has an age of at least 68 weeks.
An embodiment is the use of a mouse with knocked-in human Nox5 gene, wherein the mouse is a 129/SV mouse. In particular, the mouse has a mixed genetic background, comprising 80% 129/SV. More in particular, the mouse has a mixed genetic background, consisting of 80% 129/SV and 20% C57B16.
An embodiment is the use of the mouse with knocked-in human Nox5 gene, wherein the knocked-in human Nox5 gene is regulated by promotor tie 2.
An embodiment is the use of the mouse with knocked-in human Nox5 gene, wherein human NOX5 is expressed in endothelial cells and white blood cells of the mouse.
In a further embodiment, the invention relates to a method as described above, wherein the predetermined threshold level is the level of NOX5 determined in a sample taken from a healthy subject using an identical method, the subject not having essential arterial hypertension. In an even more preferred embodiment, the threshold level is 160 pg of NOX5 per ml. In an even more preferred embodiment, the subject also has micro-albuminuria. The sample to be used in the method described herein may be a fluid or tissue sample, preferably the sample comprises vascular endothelial cells, even more preferably the sample comprises circulating endothelial microparticles.
In a further embodiment, the invention provides a method as described above wherein the level of NOX5 is determined by measuring the level of Nox5 messenger RNA.
In a further embodiment, the invention provides a method as described above, wherein the level of NOX5 is determined by measuring the level of uncoupled nitric oxide synthase (NOS).
In a further embodiment, the invention provides a method as described above, wherein the level of uncoupled NOS is determined by measuring the level of asymmetric dimethylarginine (ADMA).
In a further embodiment, the invention provides a method as described above, wherein the sample is selected from the group comprising plasma, blood and serum.
In a further embodiment, the invention provides a method as described above, wherein the sample comprises platelet rich plasma containing white blood cells.
In a further embodiment, the invention provides a method as described above, wherein the sample comprises platelet poor plasma.
The invention further relates to a compound selected from the group consisting of sepiapterin, L-citrulline, L-arginine, tetrahydrobiopterin, folic acid and a NOX5 inhibitor for use in the treatment of a subject with essential arterial hypertension.
In a further embodiment, the invention relates to a compound for use as described above wherein the subject was diagnosed with essential arterial hypertension using a method as described herein, prior to the treatment.
In a further embodiment, the invention relates to a compound for use as described above wherein the treatment comprises the administration of a compound selected from the group consisting of sepiapterin, L-citrulline, L-arginine, tetrahydrobiopterin, folic acid and a NOX5 inhibitor to the subject and wherein the compound is administered in such quantity that the level of the compound is normalized in the fluid or tissue from which the sample was taken.
In a further embodiment, the invention relates to a compound for use as described above wherein the treatment comprises a step of measuring the level of NOX5 as described herein.
In a further embodiment, the invention relates to the use of an aged NOX5 knock-in an animal model to discover and develop therapeutics and diagnostics for the use in NOX5- and uncoupled NOS-dependent essential arterial hypertension Examples
Example 1: Study DesignHuman subjects sample size was determined by G*Power software. For mice, we used a power analysis according to the formula n=2x s2x (Za/2+Zb)2/D2 (L. Sachs, Angewandte Statistik, Springer, 1983, Berlijn, Springer Verlag). Human subjects with history or clinical evidence of angina, myocardial infarction, congestive heart failure, peripheral vascular disease, inflammatory disease, or any disease predisposing to vasculitis were excluded. Causes of secondary hypertension were excluded by appropriate investigations. Patients with stage 4 and 5 chronic kidney disease (GFR<30 mL/min/1.73 m2) were also excluded. Human samples were allocated to different group based on blood pressure and albuminuria values. Mice were allocated to experimental groups according to genotypes. Investigators were blinded to the experimental groups. Replicate experiments were successful. All experiments were reproduced at least three times with independent biological samples.
Example 2: In-Silico MethodsWe extracted a molecular subnetwork from experimentally validated protein-protein interactions from the IID [19] database (interactome) using NOX family members and nitric oxide-cyclic GMP related proteins as seed nodes. This set of seeds comprises NOX1, NOX3, NOX4, NOX5, NOS1, NOS3, GUCYA1, GUCYA2, GUCYB1, PDE5A, PDE9A and PRKG1. We obtained the subnetwork induced by all first neighbours of the seed genes from the interactome. The induced subnetwork was then pruned according to the subnetwork-participation-degree (SPD), defined as the degree of the node (protein) inside the subnetwork normalized by the degree of the node in the full interactome. The SPD quantifies how enriched the interactions of a given protein are in a given subnetwork. This way, we emerged a weighted disease module, which is represented by a set of connected components and some single nodes. We selected an SPD cut-off corresponding to 80% of the cumulative sum of the percentage of the nodes as a cut-off value in the pruning step, as this includes most module-specific interactions while excluding most non-specific nodes. The final subnetwork consisted of 56 proteins and 83 protein-protein interactions.
Moreover, we applied the two top-ranked disease network module identification methods from the Module Identification DREAM Challenge [21] to the interactome. We selected these methods from two complementary categories of methods, global and local. The main difference between these two methods is that global methods exploit the global structure information of PPI networks, while the local methods considers only local neighbour information. The global modularity optimization method (M1) of the DREAM challenge bundled in the MONET tool and the agglomerative local method (L1) from SPICi tool [23] have been selected (as best-performers in their categories) and applied to find disease modules in the interactome. Note that M1 is an ensemble approach combining multiple module detection algorithms to avoid suboptimal partitions resulting from individual algorithms [22], which notably works without any seed nodes in this tool. The agglomerative L1 method clusters the network greedily, starting from automatically selected local seeds with high weighted degree. This algorithm improves local density of modules in the neighboring region of seed nodes.
Example 3: Human Study ParticipantsWe designed the current study on the basis of a previous study in which we had enrolled consecutive outpatients with essential primary hypertension and a baseline estimated GFR 230 mL/min/1.73 m2 at Taipei Veterans General Hospital between April 2008 and December 2008 [93, 94]. Hypertension was defined as a systolic blood pressure ≥140 mmHg, a diastolic blood pressure ≥90 mmHg, or use of antihypertensive drugs. Subjects with history or clinical evidence of angina, myocardial infarction, congestive heart failure, peripheral vascular disease, inflammatory disease, or any disease predisposing to vasculitis were excluded. Causes of secondary hypertension were excluded by appropriate investigations. Patients with stage 4 and 5 chronic kidney disease (GFR <30 mL/min/1.73 m2) were also excluded. Medical history, including cardiovascular risk factors, previous and present cardiovascular events, and current medication regimen, was obtained during a personal interview and from medical files. Weight, height, and waist circumference were measured and body mass index (BMI) was calculated. Brachial blood pressure was measured by a physician with a mercury sphygmomanometer after patients sat for 15 minutes or longer. The average of 3 measurements was used for the analysis.
Example 4: Blood and Urine MeasurementsVenous blood samples were collected from all patients after 8 hours of overnight fasting for measurement. The blood samples were centrifuged at 3000 rpm for 10 minutes immediately after collection, and the plasma samples were kept frozen at −70° C. until analysis. Each standard and plasma sample was analyzed twice, and the mean value was used in all subsequent analyses. The plasma high-sensitivity C-reactive protein (hs-CRP) level was determined using a latex-enhanced immuno-nephelometric assay (Dade Behring, Marburg, Germany). Plasma N-terminal pro b-type natriuretic peptide (NT-proBNP) was determined by a sandwich immunoassay (EIMA) with two antibodies (Cortez Diagnostics, Calabasas, Calif., USA). Plasma ADMA levels were measured by ADMA Fast ELISA kit (DLD Diagnostika GMBH, Hamburg, Germany). Overnight urine samples were obtained for measurement of the albumin excretion rate. Normo-albuminuria was defined as albumin excretion rate of less than 20 mg/min, moderately increased albuminuria (previously known as micro-albuminuria) was defined as albumin excretion rate of 20-200 mg/min, and severely increased albuminuria (previously known as macro-albuminuria) was defined as albumin excretion rate more than 200 mg/min.
Example 5: Endothelial Microparticles Extraction and Measurement of NOX5CD144+ microparticles were isolated as described with modifications [95, 96]. Briefly, Dynabeads G (Invitrogen, Carlsbad, Calif.) were washed with PBS containing 0.1% BSA and then reconstituted with PBS. Anti-CD144 antibody (Santa Cruz Biotechnology, Dallas, Tex.) which specifically targets endothelial cells was mixed with prewashed Dynabeads G for 2 hours and then incubated with plasma samples at 1:200 dilution overnight at 4° C. After precipitation, Dynabeads G were washed with PBS and 1% Tween-20 three times. The purity of CD144+ MPs, determined by FACS analysis, was 70% *5.6%. With the use of FITC-conjugated beads as size references, the size of such particles was assessed to be <0.5 μm in diameter. Human NADPH oxidase 5 (NOX5) levels were measured using commercially available enzyme-linked immunosorbent assay (ELISA, Cusabio Technology LLC, Houston, Tex.) kit according to the manufacturer's instructions. Samples were stored at −70° C. from date of collection in 2008 until testing for NOX5 in 2014 (totally 50 samples were available). The intra-assay and inter-assay variation coefficients of the tests were <8% and <10%, respectively.
Example 6: AnimalsMice naturally do not express the NOX5 gene, therefore, we have generated and validated humanized NOX5 Knock-in (KI) mice as previously described [31]. The mice were 80% 129/SV/20% C57B16 mice, as described [31]. Briefly, the model was developed using the hypoxanthine phospho-ribosyl-transferase (Hprt) targeted transgenic approach under the control of the Tie2 promoter. Therefore, our NOX5 KI mice express the NOX5 in endothelial and white blood cells which mimic the physiological human expression of NOX5. Expression of NOX5 in the KI mice tissues was previously validated by quantitative real-time PCR and compared to Wild Type (WT) mice [31]. Age- and gender-matched groups of male and female mice (9-15 weeks old, n=19-20) and (68-87 weeks old, n=31-33) were used. All mice were allowed free access to water and food in a temperature-regulated room (22° C.) and placed in a 12 h light-dark cycle.
Example 7: Blood Pressure Recording (Telemetry)NOX5 KI and WT Mice were anaesthetized with isoflurane (induction, 3-4%; maintenance, 1.5-2.5%) and echocardiography (ultrasound) was performed (
After mice were sacrificed, thoracic aortae, femoral and saphenous arteries were dissected free from perivascular adipose tissue and mounted in a wire myograph (DMT, Aarhus, DK). The organ chamber was filled with Krebs-Ringer bicarbonate-buffered salt solution (KRB) that was continuously aerated with 95% O2/5% CO2 and maintained at 37° C. Passive stretch procedure was performed to mimic the physiologically relevant internal lumen diameter as previously described [100]. Arterial contractile and relaxing responses were recorded at lumen diameters corresponding to a distending pressure of 100 mmHg in thoracic aorta and femoral artery and at 90% of this diameter in the resistance-sized saphenous artery. This is justified because diastolic arterial blood pressure did not differ significantly between the aged KI and WT mice. In view of the comparable diameter-tension relationships, these diameters did not differ significantly between the two mouse strains (
Superoxide was measured in femoral arteries using the florescence dye dihydroethidium (DHE) (Thermo Scientific Technology, The Netherlands). Frozen femoral arteries cryo-sections were fixated in 4% paraformaldehyde (PFA) in PBS and then incubated with 2 μM DHE for 30 minutes at 37° C. After three washing steps with PBS, slices were incubated with DAPI (Sigma-Aldrich, The Netherlands) 2 pg/ml for 10 min. Sections were washed in PBS and then mounted using a Dako Fluorescence Mounting Medium (S3023, Agilent Technologies). Immunofluorescent signals were viewed using a Leica DM13000 B fluorescence microscope. Some arteries were pre-treated with 500 μM L-NAME for 30 min at 37° C. before performing the DHE staining.
Example 10: RNA Extraction, cDNA Synthesis and Quantitative Real-Time PCRThoracic aortae, femoral arteries and saphenous arteries were isolated from mice and immediately submerged in RNAlater solution (Thermo Fisher Scientific). RNA was extracted using RNeasy® Micro Kit (Qiagen) according to the manufacturer's protocol. cDNA was synthesized from 1 pg total RNA in 20 μl reactions using High Capacity cDNA Reverse Transcription Kit (Thermo Fisher Scientific). After synthesis, the cDNA was stored at −20° C.
RT-qPCR was performed on CFX96™ Real-Time PCR Detection System (Bio-Rad). All reactions were performed in triplicates in a total volume of 20 μl each using TaqMan® Universal PCR Master Mix (Applied Biosystems—Life Technologies) according to manufacturer's instructions. 3 μl cDNA was used as template and pre-designed TaqMan® primers of β-actin and Nox5 were used. The specific assay ID for the primers used are shown in Supplementary Table 1. The standard PCR conditions were as follows: 10 min at 95° C., followed by 15 s at 95° C. and 1 min at 60° C., 59 repeats. The amount of mRNA was normalized to the measured expression of β-actin mRNA.
Example 11: Statistical AnalysisAll human and animal data are expressed as the mean t SEM for numeric variables and as the number (percentage) for categorical variables. Comparisons of continuous variables between the two mice groups were performed by unpaired two-tailed Student's t-test and among the three human groups by one-way analysis of variance (ANOVA) followed by Tukey's multiple comparisons test (post-hoc test). Comparisons of categorical variables among the human groups were assessed by a χ2 (chi square). Comparisons between the two mice groups, in telemetry data were done by two-way repeated measures ANOVA and in myograph by ordinary two-way ANOVA, followed by Sidak's multiple comparisons test. For the subgroup analysis of the NOX5 levels in human subjects, a frequency analysis was carried out, where the bin width is calculated using Sturges' rule [103]. To assess the modality of the data, the output frequencies were fitted with a single Gaussian and sum of two Gaussian distributions, and a two-tailed F-test with null hypothesis as Gaussian and alternative hypothesis as sum of two-Gaussians was performed. Additionally, the adjusted r-squared values were compared to select the best fitting distribution for the sample. Given the bimodal nature of the sample, the area under each Gaussian distribution was calculated using the formula “Amplitude*SD/0.3989” and subsequently the proportion of NOX5 mechanotype was reported as the ratio between the two distributions. Data were analyzed using GraphPad Prism Version 8.2 (GraphPad Software Inc., San Diego, Calif.). A p-value of less than 0.05 was considered to indicate statistical significance after multiple testing correction.
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Claims
1. A method for detection of a hypertension endotype in a human patient suffering from essential arterial hypertension, wherein said endotype is defined by an increased level of circulating NADPH oxidase 5 protein (NOX5) compared to the level of circulating NOX5 in a human subject not suffering from hypertension, the method comprising the steps of:
- (a) obtaining a fluid sample from the human patient who suffers from essential arterial hypertension, selected from the group comprising plasma, blood and serum, wherein the fluid sample comprises circulating endothelial microparticles;
- (b) isolating the endothelial microparticles from the fluid sample provided in step (a); and
- (c) measuring NOX5 in the endothelial microparticles of step (b) using a protein detection assay and determining the concentration of NOX5 in the fluid sample in pg NOX5 per ml fluid sample,
- wherein it is concluded that the human patient suffers from the hypertension endotype if the concentration of NOX5 as determined in step (c) is at least 160 pg NOX5 per ml of the fluid sample.
2. The method for detection according to claim 1, wherein the fluid sample is a plasma sample.
3. The method for detection according to claim 1, wherein the human patient suffers from hypertension as defined as a systolic blood pressure of at least 140 mmHg, a diastolic blood pressure of at least 90 mmHg, or use of an antihypertensive drug.
4. The method for detection according to claim 1, wherein the human patient does not have a history or clinical evidence of any of: angina, myocardial infarction, congestive heart failure, peripheral vascular disease, inflammatory disease and any disease predisposing to vasculitis, and wherein the human subject does not have stage 4 or stage 5 chronic kidney disease.
5.-13. (canceled)
14. A method for the detection of a hypertension endotype in a human patient suffering from essential arterial hypertension, wherein said endotype is hypertension characterized by being the method comprising the steps of:
- accompanied by renal vascular leakage as established by the occurrence of microalbuminuria; or
- associated with the risk for developing renal vascular leakage apparent as development of microalbuminuria,
- (a) obtaining a fluid sample from the human patient who suffers from essential arterial hypertension, selected from the group comprising plasma, blood and serum, wherein the fluid sample comprises circulating endothelial microparticles;
- (b) isolating the endothelial microparticles from the fluid sample provided in step (a); and
- (c) measuring NADPH oxidase 5 protein (NOX5) in the endothelial microparticles of step (b) using a protein detection assay and determining the concentration of NOX5 in the fluid sample in pg NOX5 per ml fluid sample,
- wherein it is concluded that the human patient has the hypertension endotype if the concentration of NOX5 is at least 160 pg NOX5 per ml of the fluid sample.
15. The method for the detection according to claim 14, wherein the human patient has a systolic arterial blood pressure of at least 140 mmHg and a diastolic arterial blood pressure of at least 90 mmHg at two days.
16. The method for the detection according to claim 14, wherein in step (a) the fluid sample is a plasma sample.
17. The method for the detection according to claim 14, wherein in step (c) the protein detection assay is an enzyme-linked immumnsorbent assay.
18.-26. (canceled)
27. A method of use of a mouse with knocked-in human Nox5 gene to discover and develop therapeutics and methods for detection, for the use in NOX5-dependent hypertension in a subject.
28. The method of use according to claim 27, wherein the mouse has an age of at least 68 weeks.
29. The method of use according to claim 27, wherein the mouse is a 129/SV mouse.
30. The method of use according to claim 27, wherein the mouse has a genetic background comprising 80% 129/SV.
31. The method of use according to claim 27, wherein the mouse has a genetic background consisting of 80% 129/SV and 20% C57BI6.
32. The method of use according to claim 27, wherein the knocked-in human Nox5 gene is regulated by promotor tie 2.
33. The method of use according to claim 27, wherein human NOX5 is expressed in endothelial cells and white blood cells of the mouse.
34. The method for the detection according to claim 1, wherein in step (c) the protein detection assay is an enzyme-linked immunosorbent assay.
Type: Application
Filed: May 21, 2021
Publication Date: Jul 20, 2023
Applicants: Universiteit Maastricht (Maastricht), Academisch Ziekenhuis Maastricht (Maastricht)
Inventors: Harald Horst Heinz Wilhelm Schmidt (Aachen), Mahmoud Hassan Mahmoud Elbatrik (Maastricht), Hermann Alois Martin Mucke (Vienna)
Application Number: 17/927,703