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Renin inhibitor

January 01, 1970

Renin inhibitors are pharmaceutical drugs inhibiting the activity of renin that is responsible for hydrolyzing angiotensinogen to angiotensin I,[2][3][4] which in turn reduces the formation of angiotensin II that facilitates blood pressure.[5][6]

Renin inhibitor
Drug class
Aliskiren,[1] the first renin inhibitor to be marketed
Class identifiers
UseHypertension
ATC codeC09XA
Biological targetRenin
Clinical data
Drugs.comDrug Classes
Legal status
In Wikidata

Renin inhibitor is often preceded by direct, called direct renin inhibitor in order to distinguish its mechanism from other renin–angiotensin–aldosterone system-interfering drugs such as angiotensin converting enzyme inhibitors (ACEIs), angiotensin receptor blockers (ARBs) and aldosterone receptor antagonists.[6]

These drugs inhibit the first and rate-limiting step of the renin–angiotensin–aldosterone system (RAAS), namely the conversion of angiotensinogen to angiotensin I. This leads to a totality in absence of angiotensin II based on the rationale that renin only acts to inhibit this step unlike Angiotensin Converting Enzyme which is also involved in other biochemical reactions. Since the 1970s, scientists have been trying to develop potent inhibitors with acceptable oral bioavailability.[7][8] The process was difficult and took about three decades. The first and second generations faced problems such as poor bioavailability and lack of potency. Finally, the third generation was discovered. These compounds were nonpeptidic renin inhibitors, had acceptable oral bioavailability and were potent enough for clinical use. The first drug in this class was aliskiren, which received a marketing approval in 2007.[7] As of June 2020, it is the only renin inhibitor on the market.

History edit

In 1896, the Finnish physiologist Robert Tigerstedt and the Swedish physician Per Bergman did an experiment on kidneys and the circulatory system in rabbits. They observed that blood pressure rose in the rabbits when extracts of the kidneys were injected into their jugular veins.[9][10] They also discovered this substance responsible for higher blood pressure was produced in the renal cortex, and they named it renin.[10] Although this experiment laid the foundation for future investigations into the RAAS pathway, it had little impact on the scientific community at that time.[9][11] In 1934, when Goldblatt published his work in renal ischaemia, renin came into focus again. The importance of renin in the pathogenesis of cardiovascular disease was, however, not fully understood until in the 1970s, and 20 years later the first renin inhibitors went to clinical trials.[7]

Pepstatin, which was described in 1972, was the first synthetic renin inhibitor, but poor pharmacokinetic properties prevented it from entering in vivo investigations.[8][12] The first generation of renin inhibitors, such as H-142, were peptide analogues of angiotensinogen.[13] However, these inhibitors had also limited drug-like properties.[7][12] Hopes of breakthrough appeared in 1982 when development of the second generation renin inhibitors began.[7] This generation consisted of peptide-like compounds, such as remikiren, enalkiren and zanikiren.[11] They had more drug-like rather than substrate-like properties, and in 1990 they went to clinical trials. The second generation had its limitations and never completed clinical trials.[7]

Aliskiren, the only renin inhibitor to go into phase III clinical trials, is not structurally related to peptides, which makes it a third-generation renin inhibitor.[7][14] The first clinical trial was performed in 2000 in healthy volunteers.[15] In 2007, aliskiren was approved by the US Food and Drug Administration and the European Medicines Agency as a treatment for hypertension.[7] A systematic review by the Cochrane Hypertension group found the maximum recommended dose of aliskiren produced an appreciable decline in blood pressure over placebo.[16]

 
Timeline: Discovery and development of renin inhibitors

The renin–angiotensin–aldosterone system edit

 
Renin–angiotensin–aldosterone system and potential steps of blockage

The renin–angiotensin–aldosterone system (RAAS) plays a key role in the pathology of cardiovascular disease, hypertension, diabetic kidney disease and heart failure.[17] Under normal conditions, stimulation of the RAAS occurs in response to threats that compromise blood pressure stability, such as hypotension, blood loss and excessive loss of sodium and water. Blood pressure depends on total peripheral resistance and cardiac output.

The highly selective aspartic protease renin is secreted from the juxtaglomerular apparatus, which is the only source of active renin,[18] although its precursor, prorenin, can be secreted by other tissues, such as the salivary glands, brain, heart and blood vessels.[18][19][20] Renin is a circulating enzyme that acts on a circulating peptide, angiotensinogen.[21] Renin cleaves the peptide at the Leu10–Val11 bond, and this reaction is the rate-determining step of the RAAS.[22] This leads to the product angiotensin I (Ang I) which is a decapeptide. Ang I is broken down by the angiotensin-converting enzyme (ACE) to the active octapeptide angiotensin II (Ang II), which is the principal effector of the RAAS.[21] Ang II stimulates renal sodium retention; promotes aldosterone secretion; causes vasoconstriction, and increases sympathetic nervous system activity.[20][23] Ang II also provides a negative feedback to the system by inhibiting renin release by the juxtaglomerular apparatus.[23] Ang II interacts with at least two classes of Ang II receptors, AT1 and AT2.[20] This mechanism, which runs from renin through Ang II and to aldosterone, as well as the negative feedback that Ang II has on renin secretion, is known as RAAS.[23] The net effect is to increase blood pressure, which in normal physiology is necessary in order to maintain homeostasis.

It is suspected that essential hypertension, a heterogeneous disorder whose long-term effects can be end organ damage, can involve at least in some cases an overactivity of this system, which several types of medications attempt to counter.[21] Renin concentration in blood plasma tends to be higher in younger people with hypertension when vasoconstriction may be the main reason for high blood pressure. Conversely, renin is lower in older people or in people of African American or African Caribbean ethnicity when salt retention may contribute more to elevated blood pressure.[21] However, the role of plasma renin levels in the etiology and management of hypertension is disputed.[24]

Mechanism of action edit

Renin inhibitors bind to the active site of renin and inhibit the binding of renin to angiotensinogen, which is the rate-determining step of the RAAS cascade.[21] Consequently, renin inhibitors prevent the formation of Ang I and Ang II. Renin inhibitors may also prevent Ang-(1-7), Ang-(1-9) and Ang-(1-5) formation,[25] although it is not known if this is clinically important. Renin is highly selective for its only naturally occurring substrate which is angiotensinogen, and the incidence of unwanted side effects with a renin inhibitor is infrequent.[26] and similar to angiotensin II receptor antagonists.[27] Ang II also functions within the RAAS as a negative feedback to suppress further release of renin. A reduction in Ang II levels or blockade of angiotensin receptors will suppress the feedback loop and lead to increased plasma renin concentrations (PRC) and plasma renin activity (PRA). This can be problematic for ACE inhibitor and angiotensin II receptor antagonist therapy since increased PRA could partially overcome the pharmacologic inhibition of the RAAS cascade. Because renin inhibitors directly affect renin activity, decrease of PRA despite the increased PRC (from loss of the negative feedback) may be clinically advantageous.[28]

Drug discovery and development edit

Pepstatin – the first renin inhibitor edit

Pepstatin was the first synthetic renin inhibitor. It is of microbial origin and is an N-acyl-pentapeptide, more accurately: isovaleryl-L-valyl-L-valyl-statyl-L-alanyl-statine.[8][29] Pepstatin was found to be a potent competitive inhibitor of most aspartic proteases, but a weak inhibitor of renin.[30] Originally, it was thought to be effective in the treatment of duodenal ulcers, and went through clinical trials, but had no success.[31][32] Statine, an amino acid, is thought to be responsible for the inhibitory activity of pepstatin, because it mimics the tetrahedral transition state of the peptide catalysis.[33] Because of hydrophobic properties of statine, pepstatin has very low solubility in physiological media.[34] Since it had low potency and poor solubility, it did not enter in vivo studies.

First generation: peptide analogues edit

 
H-142[clarification needed]

This generation consists of two groups of compounds, either peptide analogues of the prosegment of renin[35] or peptide analogues of the amino-terminal part of the substrate angiotensinogen.[13][36][37] The drugs in the latter group seemed to be effective in inhibiting renin activity and lowering blood pressure in both animals and humans.[38] Unfortunately, they had to be given parenterally because of poor bioavailability. They also turned out to have short durations of action, low potencies and their ability to lower blood pressure was inadequate. None of these drugs completed clinical investigations.[28]

Second generation: peptide mimetics edit

 
Remikiren, a second-generation renin inhibitor

Compounds in this generation were more potent, more stable and had longer durations of action. One of these, CGP2928, a peptidomimetic compound, was the first renin inhibitor proven effective when taken orally. Tested on marmosets, it was only active at high doses.[12] Development of new drugs in the second generation continued to improve pharmacokinetic properties. Remikiren, enalkiren and zankiren were then discovered. These were peptidomimetic inhibitors with improved structures that made them more specific, potent and stable. Unfortunately, clinical development was terminated because the drugs had poor oral bioavailability (poorly absorbed and rapidly metabolized) and lowering blood pressure activity still remained low.[7][22][28]

Third generation: non-peptides edit

 
Aliskiren, the third-generation renin inhibitor

Aliskiren, an orally active non-peptide renin inhibitor, was the first drug in its class on the market. It is used to treat hypertension as monotherapy or in combination with other antihypertensive agents.[7][39] The key to the discovery of aliskiren was crystallography and molecular modeling techniques. Now, a solution has been found to the problem that impeded the development of the renin inhibitors of the previous generations. Non-peptide substances were known to be able to solve the problems of poor pharmacokinetic properties and low specificity. This led to the design of small molecules, non-peptide inhibitors, which were very potent and specific of human renin.[22][40]

However, caused by their chemical structure even third-generation renin inhibitors are difficult to resorb by the human body and their oral bioavailability is often below 2%.

Binding and structure activity relationship of renin inhibitors edit

The renin molecule is a monospecific enzyme that belongs to the aspartic protease family.[41] Its structure is complex and consists of two homologous lobes that fold mainly in a β-sheet conformation.[22] Between the two lobes, deep within the enzyme, resides the active site, and its catalytic activity is due to two aspartic acid residues (Asp32 and Asp 215, one from each lobe in the renin molecule).[42] A flexible flap made from amino acids formed in a β-hairpin closes the active site by covering the cleft.[43] The renin molecule contains both hydrophobic and hydrophilic amino acids. The hydrophilic ones tend to be on the outside of the molecule, while the hydrophobic ones tend to be more on the inside and form the active site, a large hydrophobic cavity[44] that can accommodate a ligand with at least seven residues. The principal connection between a ligand and the enzyme is by hydrogen bonding. The residues are named after their places in the ligand, the residues closest to the cleavage site are named P1 and P1′ and they bind into the S1 and S1′ pockets, respectively. There are four S pockets, and three S′ pockets (table 1). The pockets alternate on either side of the backbone in the ligand. This alternation affects the orientation of the pockets, making the S3 and S1 pockets arrange together and the S2 pocket close to both S4 and S1′ pockets.[43] Evidence suggests the closely arranged S1 and S3 pockets merge to form a spacious superpocket.[45] Ligands that fill the superpocket have greater potency than those which do not, occupying increases potency 200-fold. These ligands can be structurally diverse and form van der Waals bonds to the surface of the superpocket.[11] From the S3 pocket stretches a binding site distinct for renin, the S3sp subpocket.[41] The S3sp subpocket can accommodate both hydrophobic and polar residues, the pocket can accommodate three water molecules, but has also lipophilic nature. The S3sp subpocket is not conformationally flexible, so the residues occupying the pocket must have certain characteristics. They can not be sterically demanding and must have reasonably high number of rotatable bonds and be able to connect with hydrogen bonds. The S2 pocket is large, bipartite and hydrophobic, but can accommodate both hydrophobic and polar ligands. This diversity of possible polarity offers the P2 residue opportunity of variation in its connection to the enzyme. The S3-S1 and the S3sp subpockets have been the main target of drug design, but recent discoveries have indicated other sites of interest. Interactions to the pockets on the S′ site have been proven to be critical for affinity, especially the S1′ and S2′, and in vitro tests have indicated the interaction with the flap region could be important to affinity.[11]

 
Binding pockets with which aliskiren connects
Characteristics of each pocket and the importance each residue in the ligand has to binding
Pocket Characteristics[11] Subsite Importance to binding[11][46]
S4 Hydrophobic P4 Relatively important for binding
S3 Hydrophobic P3 Very important for binding
S3sp Equally hydrophobic/-philic P3 side chain Dramatically enhances binding affinity
S2 Large and hydrophobic P2 Important for binding
S1 Large and hydrophobic P1 NA
S1′ Primarily hydrophobic P1′ Critical for tight binding
S2′ Polar P2′ Critical for tight binding
S3′ NA P3′ Structure and presence is not as important

Interaction with both aspartic acids in the active site results in a higher affinity. Higher affinity also results by occupying more active site pockets. However, some pockets contribute more to the affinity than others. A hydrophobic interaction with the S3sp subpocket, S1 and S3 contribute to higher potency and affinity.[47] By having a large and aromatic residue in P3 increases inhibitory activity.[48] Occupation of the S3sp subpocket can increase potency by 50-fold and results in tight binding.[11]

Example of binding to the renin inhibitor: Aliskiren is a peptide-like renin inhibitor and, unlike most, it is rather hydrophilic. It blocks the catalytic function of the enzyme by occupying the S3 to S2′ pockets, except the S2 pocket. Aliskiren also binds to the S3sp subpocket and because that pocket is distinct for renin, aliskiren does not inhibit other aspartic proteases, such as cathepsin D and pepsin.[46] The side chain of aliskiren binds the S3sp subpocket ideally, and leads to its quality as an inhibitor of human renin.[11] The hydroxyl group in aliskiren forms a hydrogen bond with both oxygen atoms of the Asp32. The amine group forms a hydrogen bond with the carboxylic acid group of Gly217 and the oxygen atom of the Asp32. The methoxy group on the aromatic ring fills the S3 pocket and may possibly form a hydrogen bond with a secondary amine group of Tyr14. The amide group forms a hydrogen bond with a secondary amine group of Ser76.[47] The S1 and S1′ pockets are occupied by the two propyl groups in positions P1 and P1′.[45] The terminal amide in position P2′ anchors the amide tail in the active site by forming a hydrogen bond with Arg74 in the S2′ pocket.[49]

Current status edit

Aliskiren is effective in lowering blood pressure,[7][28] but as of 20 April 2012 the US Food and Drug Administration (FDA) issued a warning of possible risks when using aliskiren or blood pressure medicines containing aliskiren with ACE inhibitors and angiotensin receptor blockers (ARBs) in patients with diabetes or kidney (renal) impairment. They advised that such drug combinations should not be used in patients with diabetes because of the risk of causing renal impairment, hypotension, and hyperkalemia and that aliskiren should not be used with ARBs or ACE inhibitors in patients with moderate to severe renal impairment (i.e., where glomerular filtration rate [GFR] < 60 mL/min). However, they also recommend that patients should not stop taking aliskiren without talking to a healthcare professional.[50]

Aliskiren in combination with hydrochlorothiazide was approved by the FDA in 2008 under the tradename Tekturna HCT.[51][52]

In 2007, Actelion/Merck and Speedel companies announced they had the next generation of renin inhibitors in clinical research. The lead compound from Actelion/Merck has entered phase II trials. One compound from Speedel, SPP635, has completed phase IIa. The results showed it was safe and well tolerated over a four-week period, and it reduced blood pressure by 9.8 to 17.9 mmHg. In 2008, SPP635 was continuing phase II development for hypertension in diabetic patients. More renin inhibitors from Speedel are in clinical trials. Two of them, SPP1148 and SPP676, have entered phase I. Other are in preclinical phases, the compound SPP1234 and compounds from the SPP800 series.[51]

The next generation of renin inhibitors have shown potential improvements over previous generations where bioavailability has increased up to 30% in humans, and they have better tissue distribution.[51][unreliable source]

See also edit

References edit

  1. ^ Gradman AH, Schmieder RE, Lins RL, Nussberger J, Chiang Y, Bedigian MP (March 2005). "Aliskiren, a novel orally effective renin inhibitor, provides dose-dependent antihypertensive efficacy and placebo-like tolerability in hypertensive patients". Circulation. 111 (8): 1012–8. doi:10.1161/01.CIR.0000156466.02908.ED. PMID 15723979.
  2. ^ "Renin Inhibitors". CV Pharmacology. Retrieved 2020-07-22.
  3. ^ Nakano, Stephanie J.; Everitt, Melanie D. (2018). "Neurohormonal Axis and Natriuretic Peptides in Heart Failure". Heart Failure in the Child and Young Adult. Elsevier. pp. 75–86. doi:10.1016/b978-0-12-802393-8.00006-5. ISBN 978-0-12-802393-8.
  4. ^ "The Renin-Angiotensin-Aldosterone-System". TeachMePhysiology. 2020-04-28. Retrieved 2020-07-22.
  5. ^ Nussberger, Jürg (2005). "Renin Inhibitors". Hypertension. Elsevier. pp. 754–764. doi:10.1016/b978-0-7216-0258-5.50162-9. ISBN 978-0-7216-0258-5.
  6. ^ a b Lambers Heerspink, Hiddo J.; Fioretto, Paola; de Zeeuw, Dick (2014). "Pathogenesis, Pathophysiology, and Treatment of Diabetic Nephropathy". National Kidney Foundation Primer on Kidney Diseases. Elsevier. pp. 222–234. doi:10.1016/b978-1-4557-4617-0.00025-x. ISBN 978-1-4557-4617-0.
  7. ^ a b c d e f g h i j k Jensen, C.; Herold, P.; Brunner, H. R. (2008). "Aliskiren: The first renin inhibitor for clinical treatment". Nature Reviews Drug Discovery. 7 (5): 399–410. doi:10.1038/nrd2550. PMID 18340340. S2CID 19633316.
  8. ^ a b c Gross, F.; Lazar, J.; Orth, H. (1972). "Inhibition of the renin–angiotensinogen reaction by pepstatin". Science. 175 (22): 656. Bibcode:1972Sci...175..656G. doi:10.1126/science.175.4022.656. PMID 4109853. S2CID 8348522.
  9. ^ a b Ferrario, C. M.; Iyer, S. N. (1998). "angiotensin-(1-7): A bioactive fragment of the renin–angiotensin system". Regulatory Peptides. 78 (1–3): 13–18. doi:10.1016/s0167-0115(98)00134-7. PMID 9879742. S2CID 739207.
  10. ^ a b Phillips, M. I.; Schmidt-Ott, K. M. (1999). "The Discovery of Renin 100 Years Ago". News in Physiological Sciences. 14 (6): 271–274. doi:10.1152/physiologyonline.1999.14.6.271. PMID 11390864.
  11. ^ a b c d e f g h Webb, R. L.; Schiering, N.; Sedrani, R.; Maibaum, J. R. (2010). "Direct Renin Inhibitors as a New Therapy for Hypertension". Journal of Medicinal Chemistry. 53 (21): 7490–7520. doi:10.1021/jm901885s. PMID 20731374.
  12. ^ a b c Wood, J. M.; Gulati, N.; Forgiarini, P.; Fuhrer, W.; Hofbauer, K. G. (1985). "Effects of a specific and long-acting renin inhibitor in the marmoset". Hypertension. 7 (5): 797–803. doi:10.1161/01.hyp.7.5.797. PMID 3928488.
  13. ^ a b Szelke, M.; Leckie, B.; Hallett, A.; Jones, D. M.; Sueiras, J.; Atrash, B.; Lever, A. F. (1982). "Potent new inhibitors of human renin". Nature. 299 (5883): 555–557. Bibcode:1982Natur.299..555S. doi:10.1038/299555a0. PMID 6750410. S2CID 4306900.
  14. ^ Segall, L.; Covic, A.; Goldsmith, D. J. A. (2007). "Direct renin inhibitors: The dawn of a new era, or just a variation on a theme?". Nephrology Dialysis Transplantation. 22 (9): 2435–2439. doi:10.1093/ndt/gfm363. PMID 17556409.
  15. ^ Nussberger, J.; Wuerzner, G.; Jensen, C.; Brunner, H. R. (2002). "Angiotensin II suppression in humans by the orally active renin inhibitor Aliskiren (SPP100): Comparison with enalapril". Hypertension. 39 (1): E1–E8. doi:10.1161/hy0102.102293. PMID 11799102.
  16. ^ Musini, VM; Fortin, PM; Bassett, K; Wright, JM (2008). "Blood pressure lowering efficacy of renin inhibitors for primary hypertension". Cochrane Database of Systematic Reviews. 4 (4): CD007066. doi:10.1002/14651858.CD007066.pub2. PMID 18843743.
  17. ^ Weir MR (September 2007). "Effects of renin–angiotensin system inhibition on end-organ protection: can we do better?". Clin Ther. 29 (9): 1803–24. doi:10.1016/j.clinthera.2007.09.019. PMID 18035185.
  18. ^ a b Castrop H, Höcherl K, Kurtz A, Schweda F, Todorov V, Wagner C (April 2010). "Physiology of kidney renin". Physiol. Rev. 90 (2): 607–73. CiteSeerX 10.1.1.455.1972. doi:10.1152/physrev.00011.2009. PMID 20393195.
  19. ^ Tice, C. M.; Xu, Z.; Yuan, J.; Simpson, R. D.; Cacatian, S. T.; Flaherty, P. T.; Zhao, W.; Guo, J.; Ishchenko, A.; Singh, S. B.; Wu, Z.; Scott, B. B.; Bukhtiyarov, Y.; Berbaum, J.; Mason, J.; Panemangalore, R.; Cappiello, M. G.; Müller, D.; Harrison, R. K.; McGeehan, G. M.; Dillard, L. W.; Baldwin, J. J.; Claremon, D. A. (2009). "Design and optimization of renin inhibitors: Orally bioavailable alkyl amines". Bioorganic & Medicinal Chemistry Letters. 19 (13): 3541–3545. doi:10.1016/j.bmcl.2009.04.140. PMID 19457666.
  20. ^ a b c Ferrario, C. M. (2006). "Role of angiotensin II in cardiovascular disease therapeutic implications of more than a century of research". Journal of the Renin-Angiotensin-Aldosterone System. 7 (1): 3–14. doi:10.3317/jraas.2006.003. PMID 17083068.
  21. ^ a b c d e Brown, M. J. (2006). "Direct renin inhibition — a new way of targeting the renin system". Journal of the Renin-Angiotensin-Aldosterone System. 7 (2 suppl): S7–S11. doi:10.3317/jraas.2006.035. S2CID 73232791.
  22. ^ a b c d Rahuel, J.; Rasetti, V.; Maibaum, J.; Rüeger, H.; Göschke, R.; Cohen, N. C.; Stutz, S.; Cumin, F.; Fuhrer, W.; Wood, J. M.; Grütter, M. G. (2000). "Structure-based drug design: The discovery of novel nonpeptide orally active inhibitors of human renin". Chemistry & Biology. 7 (7): 493–504. doi:10.1016/S1074-5521(00)00134-4. PMID 10903938.
  23. ^ a b c Hsueh, W. A.; Wyne, K. (2011). "Renin–angiotensin–Aldosterone System in Diabetes and Hypertension". The Journal of Clinical Hypertension. 13 (4): 224–237. doi:10.1111/j.1751-7176.2011.00449.x. PMC 8673350. PMID 21466617. S2CID 23032701.
  24. ^ Moser M, Izzo JL (2003). "Plasma renin measurement in the management of hypertension: the V and R hypothesis". The Journal of Clinical Hypertension. 5 (6): 373–6. doi:10.1111/j.1524-6175.2003.02870.x. PMC 8099254. PMID 14688491. S2CID 221263755.
  25. ^ Müller, D. N.; Derer, W.; Dechend, R. (2008). "Aliskiren—mode of action and preclinical data". Journal of Molecular Medicine. 86 (6): 659–662. doi:10.1007/s00109-008-0330-6. PMID 18443751. S2CID 23697321.
  26. ^ Weir, M.; Bush, C.; Anderson, D.; Zhang, J.; Keefe, D.; Satlin, A. (2007). "Antihypertensive efficacy, safety, and tolerability of the oral direct renin inhibitor aliskiren in patients with hypertension: A pooled analysis". Journal of the American Society of Hypertension. 1 (4): 264–277. doi:10.1016/j.jash.2007.04.004. PMID 20409858.
  27. ^ Gao D, Ning N, Niu X, Wei J, Sun P, Hao G (May 2011). "Aliskiren vs. angiotensin receptor blockers in hypertension: meta-analysis of randomized controlled trials". Am. J. Hypertens. 24 (5): 613–21. doi:10.1038/ajh.2011.3. PMID 21293386.
  28. ^ a b c d Staessen, J. A.; Li, Y.; Richart, T. (2006). "Oral renin inhibitors". The Lancet. 368 (9545): 1449–1456. doi:10.1016/S0140-6736(06)69442-7. PMID 17055947. S2CID 20729350.
  29. ^ Umezawa, H.; Aoyagi, T.; Morishima, H.; Matsuzaki, M.; Hamada, M.; Takeuchi, T. (1970). "Pepstatin, a new pepsin inhibitor produced by Actinomycetes". The Journal of Antibiotics. 23 (5): 259–262. doi:10.7164/antibiotics.23.259. PMID 4912600.
  30. ^ Fisher, N. D. L.; Hollenberg, N. K. (2005). "Renin Inhibition: What Are the Therapeutic Opportunities?". Journal of the American Society of Nephrology. 16 (3): 592–599. doi:10.1681/ASN.2004100874. PMID 15703270.
  31. ^ Bonnevie, O.; Svendsen, L. B.; Holst-Christensen, J.; Johansen, T. S.; Søltoft, J.; Christiansen, P. M. (1979). "Double-blind randomised clinical trial of a pepsin-inhibitory pentapeptide (pepstatin) in the treatment of duodenal ulcer". Gut. 20 (7): 624–628. doi:10.1136/gut.20.7.624. PMC 1412504. PMID 385457.
  32. ^ Svendsen, L. B.; Christiansen, P. M.; Bonnevie, O. (1979). "Gastric ulcer therapy with a pepsin-inactivating peptide, pepstatin: A double-blind randomized clinical trial". Scandinavian Journal of Gastroenterology. 14 (8): 929–932. PMID 394302.
  33. ^ Marciniszyn Jr, J.; Hartsuck, J. A.; Tang, J. (1976). "Mode of inhibition of acid proteases by pepstatin". The Journal of Biological Chemistry. 251 (22): 7088–7094. doi:10.1016/S0021-9258(17)32945-9. PMID 993206.
  34. ^ Eid, M.; Evin, G.; Castro, B.; Menard, J.; Corvol, P. (1981). "New renin inhibitors homologous with pepstatin". The Biochemical Journal. 197 (2): 465–471. doi:10.1042/bj1970465. PMC 1163147. PMID 7034718.
  35. ^ Cumin, F.; Evin, G.; Fehrentz, J. A.; Seyer, R.; Castro, B.; Menard, J.; et al. (1985). "Inhibition of human renin by synthetic peptides derived from its prosegment". J Biol Chem. 260 (16): 9154–9157. doi:10.1016/S0021-9258(17)39344-4. PMID 3894354.
  36. ^ Szelke, M.; Leckie, B. J.; Tree, M.; Brown, A.; Grant, J.; Hallett, A.; et al. (1982). "H-77: a potent new renin inhibitor. In vitro and in vivo studies". Hypertension. 4 (3 Pt 2): 59–69. doi:10.1161/01.HYP.4.3_Pt_2.59. PMID 7040240.
  37. ^ Tree, M.; Atrash, B.; Donovan, B.; Gamble, J.; Hallett, A.; Hughes, M.; Jones, D. M.; Leckie, B.; Lever, A. F.; Morton, J. J.; Szelke, M. (1983). "New inhibitors of human renin tested in vitro and in vivo in the anaesthetized baboon". Journal of Hypertension. 1 (4): 399–403. doi:10.1097/00004872-198312000-00013. PMID 6398331.
  38. ^ Webb, D. J.; Manhem, P. J.; Ball, S. G.; Inglis, G.; Leckie, B. J.; Lever, A. F.; Morton, J. J.; Robertson, J. I.; Murray, G. D.; Ménard, J.; Hallett, A.; Jones, D. M.; Szelke, M. (1985). "A study of the renin inhibitor H142 in man". Journal of Hypertension. 3 (6): 653–658. doi:10.1097/00004872-198512000-00013. PMID 3910726.
  39. ^ Riccioni, Graziano (2013-06-14). "The role of direct renin inhibitors in the treatment of the hypertensive diabetic patient". Therapeutic Advances in Endocrinology and Metabolism. 4 (5). SAGE Publications: 139–145. doi:10.1177/2042018813490779. ISSN 2042-0188. PMC 3799297. PMID 24143271.
  40. ^ Claude Cohen, N. (2007). "Structure-Based Drug Design and the Discovery of Aliskiren (Tekturna): Perseverance and Creativity to Overcome a R&D Pipeline Challenge". Chemical Biology & Drug Design. 70 (6): 557–565. doi:10.1111/j.1747-0285.2007.00599.x. PMID 17999663. S2CID 221550002.
  41. ^ a b Winiecka, I.; Dudkiewicz-Wilczyńska, J.; Roman, I.; Paruszewski, R. (2010). "New potential renin inhibitors with dipeptide replacements in the molecule". Acta Poloniae Pharmaceutica. 67 (4): 367–374. PMID 20635532.
  42. ^ Gradman, A. H.; Kad, R. (2008). "Renin inhibition in hypertension. [Review]". J Am Coll Cardiol. 51 (5): 519–528. doi:10.1016/j.jacc.2007.10.027. PMID 18237679.
  43. ^ a b Lunney, E. A.; Hamilton, H. W.; Hodges, J. C.; Kaltenbronn, J. S.; Repine, J. T.; Badasso, M.; Cooper, J. B.; Dealwis, C.; Wallace, B. A.; Lowther, W. T. (1993). "Analyses of ligand binding in five endothiapepsin crystal complexes and their use in the design and evaluation of novel renin inhibitors". Journal of Medicinal Chemistry. 36 (24): 3809–3820. doi:10.1021/jm00076a008. PMID 8254610.
  44. ^ Matter, H.; Scheiper, B.; Steinhagen, H.; Böcskei, Z.; Fleury, V. R.; McCort, G. (2011). "Structure-based design and optimization of potent renin inhibitors on 5- or 7-azaindole-scaffolds". Bioorganic & Medicinal Chemistry Letters. 21 (18): 5487–5492. doi:10.1016/j.bmcl.2011.06.112. PMID 21840215.
  45. ^ a b Yuan, J.; Simpson, R. D.; Zhao, W.; Tice, C. M.; Xu, Z.; Cacatian, S.; Jia, L.; Flaherty, P. T.; Guo, J.; Ishchenko, A.; Wu, Z.; McKeever, B. M.; Scott, B. B.; Bukhtiyarov, Y.; Berbaum, J.; Panemangalore, R.; Bentley, R.; Doe, C. P.; Harrison, R. K.; McGeehan, G. M.; Singh, S. B.; Dillard, L. W.; Baldwin, J. J.; Claremon, D. A. (2011). "Biphenyl/diphenyl ether renin inhibitors: Filling the S1 pocket of renin via the S3 pocket". Bioorganic & Medicinal Chemistry Letters. 21 (16): 4836–4843. doi:10.1016/j.bmcl.2011.06.043. PMID 21741239.
  46. ^ a b Wood, J. M.; Maibaum, J.; Rahuel, J.; Grütter, M. G.; Cohen, N. C.; Rasetti, V.; Rüger, H.; Göschke, R.; Stutz, S.; Fuhrer, W.; Schilling, W.; Rigollier, P.; Yamaguchi, Y.; Cumin, F.; Baum, H. P.; Schnell, C. R.; Herold, P.; Mah, R.; Jensen, C.; O'Brien, E.; Stanton, A.; Bedigian, M. P. (2003). "Structure-based design of aliskiren, a novel orally effective renin inhibitor". Biochemical and Biophysical Research Communications. 308 (4): 698–705. doi:10.1016/S0006-291X(03)01451-7. PMID 12927775.
  47. ^ a b Politi, A.; Durdagi, S.; Moutevelis-Minakakis, P.; Kokotos, G.; Mavromoustakos, T. (2010). "Development of accurate binding affinity predictions of novel renin inhibitors through molecular docking studies". Journal of Molecular Graphics and Modelling. 29 (3): 425–435. doi:10.1016/j.jmgm.2010.08.003. PMID 20855222.
  48. ^ Akahane, K.; Umeyama, H.; Nakagawa, S.; Moriguchi, I.; Hirose, S.; Iizuka, K.; Murakami, K. (1985). "Three-dimensional structure of human renin". Hypertension. 7 (1): 3–12. doi:10.1161/01.hyp.7.1.3. PMID 3884499.
  49. ^ Wu, Y.; Shi, C.; Sun, X.; Wu, X.; Sun, H. (2011). "Synthesis, biological evaluation and docking studies of octane–carboxamide based renin inhibitors with extended segments toward S3′ site of renin". Bioorganic & Medicinal Chemistry. 19 (14): 4238–4249. doi:10.1016/j.bmc.2011.05.059. PMID 21708467.
  50. ^ . www.fda.gov. Archived from the original on 2012-04-22.
  51. ^ a b c Speedel Acquiring an additional 51.7% stake and announcing plans for mandatory public tender offer.TRANSACTION OVERVIEW. (2008). From Novartis: http://www.novartis.com/downloads/investors/presentations-events/other-events/2008/2008-07_speedel-backgrounder.pdf
  52. ^ Tekturna HCT (aliskiren; hydrochlorothiazide) tablets. (2011). From US Food and Drug Administration: http://www.accessdata.fda.gov/drugsatfda_docs/label/2011/022107s009lbl.pdf

External links edit

 
Wikimedia Commons has media related to renin inhibitors.
  • The Story of Aliskiren the first Renin Inhibitor - drugdesign.org
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January 01, 1970
renin, inhibitor, pharmaceutical, drugs, inhibiting, activity, renin, that, responsible, hydrolyzing, angiotensinogen, angiotensin, which, turn, reduces, formation, angiotensin, that, facilitates, blood, pressure, drug, classaliskiren, first, renin, inhibitor,. Renin inhibitors are pharmaceutical drugs inhibiting the activity of renin that is responsible for hydrolyzing angiotensinogen to angiotensin I 2 3 4 which in turn reduces the formation of angiotensin II that facilitates blood pressure 5 6 Renin inhibitorDrug classAliskiren 1 the first renin inhibitor to be marketedClass identifiersUseHypertensionATC codeC09XABiological targetReninClinical dataDrugs comDrug ClassesLegal statusIn Wikidata Renin inhibitor is often preceded by direct called direct renin inhibitor in order to distinguish its mechanism from other renin angiotensin aldosterone system interfering drugs such as angiotensin converting enzyme inhibitors ACEIs angiotensin receptor blockers ARBs and aldosterone receptor antagonists 6 These drugs inhibit the first and rate limiting step of the renin angiotensin aldosterone system RAAS namely the conversion of angiotensinogen to angiotensin I This leads to a totality in absence of angiotensin II based on the rationale that renin only acts to inhibit this step unlike Angiotensin Converting Enzyme which is also involved in other biochemical reactions Since the 1970s scientists have been trying to develop potent inhibitors with acceptable oral bioavailability 7 8 The process was difficult and took about three decades The first and second generations faced problems such as poor bioavailability and lack of potency Finally the third generation was discovered These compounds were nonpeptidic renin inhibitors had acceptable oral bioavailability and were potent enough for clinical use The first drug in this class was aliskiren which received a marketing approval in 2007 7 As of June 2020 update it is the only renin inhibitor on the market Contents 1 History 2 The renin angiotensin aldosterone system 3 Mechanism of action 4 Drug discovery and development 4 1 Pepstatin the first renin inhibitor 4 2 First generation peptide analogues 4 3 Second generation peptide mimetics 4 4 Third generation non peptides 5 Binding and structure activity relationship of renin inhibitors 6 Current status 7 See also 8 References 9 External linksHistory editIn 1896 the Finnish physiologist Robert Tigerstedt and the Swedish physician Per Bergman did an experiment on kidneys and the circulatory system in rabbits They observed that blood pressure rose in the rabbits when extracts of the kidneys were injected into their jugular veins 9 10 They also discovered this substance responsible for higher blood pressure was produced in the renal cortex and they named it renin 10 Although this experiment laid the foundation for future investigations into the RAAS pathway it had little impact on the scientific community at that time 9 11 In 1934 when Goldblatt published his work in renal ischaemia renin came into focus again The importance of renin in the pathogenesis of cardiovascular disease was however not fully understood until in the 1970s and 20 years later the first renin inhibitors went to clinical trials 7 Pepstatin which was described in 1972 was the first synthetic renin inhibitor but poor pharmacokinetic properties prevented it from entering in vivo investigations 8 12 The first generation of renin inhibitors such as H 142 were peptide analogues of angiotensinogen 13 However these inhibitors had also limited drug like properties 7 12 Hopes of breakthrough appeared in 1982 when development of the second generation renin inhibitors began 7 This generation consisted of peptide like compounds such as remikiren enalkiren and zanikiren 11 They had more drug like rather than substrate like properties and in 1990 they went to clinical trials The second generation had its limitations and never completed clinical trials 7 Aliskiren the only renin inhibitor to go into phase III clinical trials is not structurally related to peptides which makes it a third generation renin inhibitor 7 14 The first clinical trial was performed in 2000 in healthy volunteers 15 In 2007 aliskiren was approved by the US Food and Drug Administration and the European Medicines Agency as a treatment for hypertension 7 A systematic review by the Cochrane Hypertension group found the maximum recommended dose of aliskiren produced an appreciable decline in blood pressure over placebo 16 nbsp Timeline Discovery and development of renin inhibitorsThe renin angiotensin aldosterone system edit nbsp Renin angiotensin aldosterone system and potential steps of blockage The renin angiotensin aldosterone system RAAS plays a key role in the pathology of cardiovascular disease hypertension diabetic kidney disease and heart failure 17 Under normal conditions stimulation of the RAAS occurs in response to threats that compromise blood pressure stability such as hypotension blood loss and excessive loss of sodium and water Blood pressure depends on total peripheral resistance and cardiac output The highly selective aspartic protease renin is secreted from the juxtaglomerular apparatus which is the only source of active renin 18 although its precursor prorenin can be secreted by other tissues such as the salivary glands brain heart and blood vessels 18 19 20 Renin is a circulating enzyme that acts on a circulating peptide angiotensinogen 21 Renin cleaves the peptide at the Leu10 Val11 bond and this reaction is the rate determining step of the RAAS 22 This leads to the product angiotensin I Ang I which is a decapeptide Ang I is broken down by the angiotensin converting enzyme ACE to the active octapeptide angiotensin II Ang II which is the principal effector of the RAAS 21 Ang II stimulates renal sodium retention promotes aldosterone secretion causes vasoconstriction and increases sympathetic nervous system activity 20 23 Ang II also provides a negative feedback to the system by inhibiting renin release by the juxtaglomerular apparatus 23 Ang II interacts with at least two classes of Ang II receptors AT1 and AT2 20 This mechanism which runs from renin through Ang II and to aldosterone as well as the negative feedback that Ang II has on renin secretion is known as RAAS 23 The net effect is to increase blood pressure which in normal physiology is necessary in order to maintain homeostasis It is suspected that essential hypertension a heterogeneous disorder whose long term effects can be end organ damage can involve at least in some cases an overactivity of this system which several types of medications attempt to counter 21 Renin concentration in blood plasma tends to be higher in younger people with hypertension when vasoconstriction may be the main reason for high blood pressure Conversely renin is lower in older people or in people of African American or African Caribbean ethnicity when salt retention may contribute more to elevated blood pressure 21 However the role of plasma renin levels in the etiology and management of hypertension is disputed 24 Mechanism of action editRenin inhibitors bind to the active site of renin and inhibit the binding of renin to angiotensinogen which is the rate determining step of the RAAS cascade 21 Consequently renin inhibitors prevent the formation of Ang I and Ang II Renin inhibitors may also prevent Ang 1 7 Ang 1 9 and Ang 1 5 formation 25 although it is not known if this is clinically important Renin is highly selective for its only naturally occurring substrate which is angiotensinogen and the incidence of unwanted side effects with a renin inhibitor is infrequent 26 and similar to angiotensin II receptor antagonists 27 Ang II also functions within the RAAS as a negative feedback to suppress further release of renin A reduction in Ang II levels or blockade of angiotensin receptors will suppress the feedback loop and lead to increased plasma renin concentrations PRC and plasma renin activity PRA This can be problematic for ACE inhibitor and angiotensin II receptor antagonist therapy since increased PRA could partially overcome the pharmacologic inhibition of the RAAS cascade Because renin inhibitors directly affect renin activity decrease of PRA despite the increased PRC from loss of the negative feedback may be clinically advantageous 28 Drug discovery and development editPepstatin the first renin inhibitor edit Pepstatin was the first synthetic renin inhibitor It is of microbial origin and is an N acyl pentapeptide more accurately isovaleryl L valyl L valyl statyl L alanyl statine 8 29 Pepstatin was found to be a potent competitive inhibitor of most aspartic proteases but a weak inhibitor of renin 30 Originally it was thought to be effective in the treatment of duodenal ulcers and went through clinical trials but had no success 31 32 Statine an amino acid is thought to be responsible for the inhibitory activity of pepstatin because it mimics the tetrahedral transition state of the peptide catalysis 33 Because of hydrophobic properties of statine pepstatin has very low solubility in physiological media 34 Since it had low potency and poor solubility it did not enter in vivo studies First generation peptide analogues edit nbsp H 142 clarification needed This generation consists of two groups of compounds either peptide analogues of the prosegment of renin 35 or peptide analogues of the amino terminal part of the substrate angiotensinogen 13 36 37 The drugs in the latter group seemed to be effective in inhibiting renin activity and lowering blood pressure in both animals and humans 38 Unfortunately they had to be given parenterally because of poor bioavailability They also turned out to have short durations of action low potencies and their ability to lower blood pressure was inadequate None of these drugs completed clinical investigations 28 Second generation peptide mimetics edit nbsp Remikiren a second generation renin inhibitor Compounds in this generation were more potent more stable and had longer durations of action One of these CGP2928 a peptidomimetic compound was the first renin inhibitor proven effective when taken orally Tested on marmosets it was only active at high doses 12 Development of new drugs in the second generation continued to improve pharmacokinetic properties Remikiren enalkiren and zankiren were then discovered These were peptidomimetic inhibitors with improved structures that made them more specific potent and stable Unfortunately clinical development was terminated because the drugs had poor oral bioavailability poorly absorbed and rapidly metabolized and lowering blood pressure activity still remained low 7 22 28 Third generation non peptides edit nbsp Aliskiren the third generation renin inhibitor Aliskiren an orally active non peptide renin inhibitor was the first drug in its class on the market It is used to treat hypertension as monotherapy or in combination with other antihypertensive agents 7 39 The key to the discovery of aliskiren was crystallography and molecular modeling techniques Now a solution has been found to the problem that impeded the development of the renin inhibitors of the previous generations Non peptide substances were known to be able to solve the problems of poor pharmacokinetic properties and low specificity This led to the design of small molecules non peptide inhibitors which were very potent and specific of human renin 22 40 However caused by their chemical structure even third generation renin inhibitors are difficult to resorb by the human body and their oral bioavailability is often below 2 Binding and structure activity relationship of renin inhibitors editThe renin molecule is a monospecific enzyme that belongs to the aspartic protease family 41 Its structure is complex and consists of two homologous lobes that fold mainly in a b sheet conformation 22 Between the two lobes deep within the enzyme resides the active site and its catalytic activity is due to two aspartic acid residues Asp32 and Asp 215 one from each lobe in the renin molecule 42 A flexible flap made from amino acids formed in a b hairpin closes the active site by covering the cleft 43 The renin molecule contains both hydrophobic and hydrophilic amino acids The hydrophilic ones tend to be on the outside of the molecule while the hydrophobic ones tend to be more on the inside and form the active site a large hydrophobic cavity 44 that can accommodate a ligand with at least seven residues The principal connection between a ligand and the enzyme is by hydrogen bonding The residues are named after their places in the ligand the residues closest to the cleavage site are named P1 and P1 and they bind into the S1 and S1 pockets respectively There are four S pockets and three S pockets table 1 The pockets alternate on either side of the backbone in the ligand This alternation affects the orientation of the pockets making the S3 and S1 pockets arrange together and the S2 pocket close to both S4 and S1 pockets 43 Evidence suggests the closely arranged S1 and S3 pockets merge to form a spacious superpocket 45 Ligands that fill the superpocket have greater potency than those which do not occupying increases potency 200 fold These ligands can be structurally diverse and form van der Waals bonds to the surface of the superpocket 11 From the S3 pocket stretches a binding site distinct for renin the S3sp subpocket 41 The S3sp subpocket can accommodate both hydrophobic and polar residues the pocket can accommodate three water molecules but has also lipophilic nature The S3sp subpocket is not conformationally flexible so the residues occupying the pocket must have certain characteristics They can not be sterically demanding and must have reasonably high number of rotatable bonds and be able to connect with hydrogen bonds The S2 pocket is large bipartite and hydrophobic but can accommodate both hydrophobic and polar ligands This diversity of possible polarity offers the P2 residue opportunity of variation in its connection to the enzyme The S3 S1 and the S3sp subpockets have been the main target of drug design but recent discoveries have indicated other sites of interest Interactions to the pockets on the S site have been proven to be critical for affinity especially the S1 and S2 and in vitro tests have indicated the interaction with the flap region could be important to affinity 11 nbsp Binding pockets with which aliskiren connects Characteristics of each pocket and the importance each residue in the ligand has to binding Pocket Characteristics 11 Subsite Importance to binding 11 46 S4 Hydrophobic P4 Relatively important for binding S3 Hydrophobic P3 Very important for binding S3sp Equally hydrophobic philic P3 side chain Dramatically enhances binding affinity S2 Large and hydrophobic P2 Important for binding S1 Large and hydrophobic P1 NA S1 Primarily hydrophobic P1 Critical for tight binding S2 Polar P2 Critical for tight binding S3 NA P3 Structure and presence is not as important Interaction with both aspartic acids in the active site results in a higher affinity Higher affinity also results by occupying more active site pockets However some pockets contribute more to the affinity than others A hydrophobic interaction with the S3sp subpocket S1 and S3 contribute to higher potency and affinity 47 By having a large and aromatic residue in P3 increases inhibitory activity 48 Occupation of the S3sp subpocket can increase potency by 50 fold and results in tight binding 11 Example of binding to the renin inhibitor Aliskiren is a peptide like renin inhibitor and unlike most it is rather hydrophilic It blocks the catalytic function of the enzyme by occupying the S3 to S2 pockets except the S2 pocket Aliskiren also binds to the S3sp subpocket and because that pocket is distinct for renin aliskiren does not inhibit other aspartic proteases such as cathepsin D and pepsin 46 The side chain of aliskiren binds the S3sp subpocket ideally and leads to its quality as an inhibitor of human renin 11 The hydroxyl group in aliskiren forms a hydrogen bond with both oxygen atoms of the Asp32 The amine group forms a hydrogen bond with the carboxylic acid group of Gly217 and the oxygen atom of the Asp32 The methoxy group on the aromatic ring fills the S3 pocket and may possibly form a hydrogen bond with a secondary amine group of Tyr14 The amide group forms a hydrogen bond with a secondary amine group of Ser76 47 The S1 and S1 pockets are occupied by the two propyl groups in positions P1 and P1 45 The terminal amide in position P2 anchors the amide tail in the active site by forming a hydrogen bond with Arg74 in the S2 pocket 49 Current status editAliskiren is effective in lowering blood pressure 7 28 but as of 20 April 2012 the US Food and Drug Administration FDA issued a warning of possible risks when using aliskiren or blood pressure medicines containing aliskiren with ACE inhibitors and angiotensin receptor blockers ARBs in patients with diabetes or kidney renal impairment They advised that such drug combinations should not be used in patients with diabetes because of the risk of causing renal impairment hypotension and hyperkalemia and that aliskiren should not be used with ARBs or ACE inhibitors in patients with moderate to severe renal impairment i e where glomerular filtration rate GFR lt 60 mL min However they also recommend that patients should not stop taking aliskiren without talking to a healthcare professional 50 Aliskiren in combination with hydrochlorothiazide was approved by the FDA in 2008 under the tradename Tekturna HCT 51 52 In 2007 Actelion Merck and Speedel companies announced they had the next generation of renin inhibitors in clinical research The lead compound from Actelion Merck has entered phase II trials One compound from Speedel SPP635 has completed phase IIa The results showed it was safe and well tolerated over a four week period and it reduced blood pressure by 9 8 to 17 9 mmHg In 2008 SPP635 was continuing phase II development for hypertension in diabetic patients More renin inhibitors from Speedel are in clinical trials Two of them SPP1148 and SPP676 have entered phase I Other are in preclinical phases the compound SPP1234 and compounds from the SPP800 series 51 The next generation of renin inhibitors have shown potential improvements over previous generations where bioavailability has increased up to 30 in humans and they have better tissue distribution 51 unreliable source See also editACE inhibitor ACE inhibitors drug design Angiotensin Angiotensin II receptor antagonist Beta blocker Circulatory system Discovery and development of angiotensin receptor blockersReferences edit Gradman AH Schmieder RE Lins RL Nussberger J Chiang Y Bedigian MP March 2005 Aliskiren a novel orally effective renin inhibitor provides dose dependent antihypertensive efficacy and placebo like tolerability in hypertensive patients Circulation 111 8 1012 8 doi 10 1161 01 CIR 0000156466 02908 ED PMID 15723979 Renin Inhibitors CV Pharmacology Retrieved 2020 07 22 Nakano Stephanie J Everitt Melanie D 2018 Neurohormonal Axis and Natriuretic Peptides in Heart Failure Heart Failure in the Child and Young Adult Elsevier pp 75 86 doi 10 1016 b978 0 12 802393 8 00006 5 ISBN 978 0 12 802393 8 The Renin Angiotensin Aldosterone System TeachMePhysiology 2020 04 28 Retrieved 2020 07 22 Nussberger Jurg 2005 Renin Inhibitors Hypertension Elsevier pp 754 764 doi 10 1016 b978 0 7216 0258 5 50162 9 ISBN 978 0 7216 0258 5 a b Lambers Heerspink Hiddo J Fioretto Paola de Zeeuw Dick 2014 Pathogenesis Pathophysiology and Treatment of Diabetic Nephropathy National Kidney Foundation Primer on Kidney Diseases Elsevier pp 222 234 doi 10 1016 b978 1 4557 4617 0 00025 x ISBN 978 1 4557 4617 0 a b c d e f g h i j k Jensen C Herold P Brunner H R 2008 Aliskiren The first renin inhibitor for clinical treatment Nature Reviews Drug Discovery 7 5 399 410 doi 10 1038 nrd2550 PMID 18340340 S2CID 19633316 a b c Gross F Lazar J Orth H 1972 Inhibition of the renin angiotensinogen reaction by pepstatin Science 175 22 656 Bibcode 1972Sci 175 656G doi 10 1126 science 175 4022 656 PMID 4109853 S2CID 8348522 a b Ferrario C M Iyer S N 1998 angiotensin 1 7 A bioactive fragment of the renin angiotensin system Regulatory Peptides 78 1 3 13 18 doi 10 1016 s0167 0115 98 00134 7 PMID 9879742 S2CID 739207 a b Phillips M I Schmidt Ott K M 1999 The Discovery of Renin 100 Years Ago News in Physiological Sciences 14 6 271 274 doi 10 1152 physiologyonline 1999 14 6 271 PMID 11390864 a b c d e f g h Webb R L Schiering N Sedrani R Maibaum J R 2010 Direct Renin Inhibitors as a New Therapy for Hypertension Journal of Medicinal Chemistry 53 21 7490 7520 doi 10 1021 jm901885s PMID 20731374 a b c Wood J M Gulati N Forgiarini P Fuhrer W Hofbauer K G 1985 Effects of a specific and long acting renin inhibitor in the marmoset Hypertension 7 5 797 803 doi 10 1161 01 hyp 7 5 797 PMID 3928488 a b Szelke M Leckie B Hallett A Jones D M Sueiras J Atrash B Lever A F 1982 Potent new inhibitors of human renin Nature 299 5883 555 557 Bibcode 1982Natur 299 555S doi 10 1038 299555a0 PMID 6750410 S2CID 4306900 Segall L Covic A Goldsmith D J A 2007 Direct renin inhibitors The dawn of a new era or just a variation on a theme Nephrology Dialysis Transplantation 22 9 2435 2439 doi 10 1093 ndt gfm363 PMID 17556409 Nussberger J Wuerzner G Jensen C Brunner H R 2002 Angiotensin II suppression in humans by the orally active renin inhibitor Aliskiren SPP100 Comparison with enalapril Hypertension 39 1 E1 E8 doi 10 1161 hy0102 102293 PMID 11799102 Musini VM Fortin PM Bassett K Wright JM 2008 Blood pressure lowering efficacy of renin inhibitors for primary hypertension Cochrane Database of Systematic Reviews 4 4 CD007066 doi 10 1002 14651858 CD007066 pub2 PMID 18843743 Weir MR September 2007 Effects of renin angiotensin system inhibition on end organ protection can we do better Clin Ther 29 9 1803 24 doi 10 1016 j clinthera 2007 09 019 PMID 18035185 a b Castrop H Hocherl K Kurtz A Schweda F Todorov V Wagner C April 2010 Physiology of kidney renin Physiol Rev 90 2 607 73 CiteSeerX 10 1 1 455 1972 doi 10 1152 physrev 00011 2009 PMID 20393195 Tice C M Xu Z Yuan J Simpson R D Cacatian S T Flaherty P T Zhao W Guo J Ishchenko A Singh S B Wu Z Scott B B Bukhtiyarov Y Berbaum J Mason J Panemangalore R Cappiello M G Muller D Harrison R K McGeehan G M Dillard L W Baldwin J J Claremon D A 2009 Design and optimization of renin inhibitors Orally bioavailable alkyl amines Bioorganic amp Medicinal Chemistry Letters 19 13 3541 3545 doi 10 1016 j bmcl 2009 04 140 PMID 19457666 a b c Ferrario C M 2006 Role of angiotensin II in cardiovascular disease therapeutic implications of more than a century of research Journal of the Renin Angiotensin Aldosterone System 7 1 3 14 doi 10 3317 jraas 2006 003 PMID 17083068 a b c d e Brown M J 2006 Direct renin inhibition a new way of targeting the renin system Journal of the Renin Angiotensin Aldosterone System 7 2 suppl S7 S11 doi 10 3317 jraas 2006 035 S2CID 73232791 a b c d Rahuel J Rasetti V Maibaum J Rueger H Goschke R Cohen N C Stutz S Cumin F Fuhrer W Wood J M Grutter M G 2000 Structure based drug design The discovery of novel nonpeptide orally active inhibitors of human renin Chemistry amp Biology 7 7 493 504 doi 10 1016 S1074 5521 00 00134 4 PMID 10903938 a b c Hsueh W A Wyne K 2011 Renin angiotensin Aldosterone System in Diabetes and Hypertension The Journal of Clinical Hypertension 13 4 224 237 doi 10 1111 j 1751 7176 2011 00449 x PMC 8673350 PMID 21466617 S2CID 23032701 Moser M Izzo JL 2003 Plasma renin measurement in the management of hypertension the V and R hypothesis The Journal of Clinical Hypertension 5 6 373 6 doi 10 1111 j 1524 6175 2003 02870 x PMC 8099254 PMID 14688491 S2CID 221263755 Muller D N Derer W Dechend R 2008 Aliskiren mode of action and preclinical data Journal of Molecular Medicine 86 6 659 662 doi 10 1007 s00109 008 0330 6 PMID 18443751 S2CID 23697321 Weir M Bush C Anderson D Zhang J Keefe D Satlin A 2007 Antihypertensive efficacy safety and tolerability of the oral direct renin inhibitor aliskiren in patients with hypertension A pooled analysis Journal of the American Society of Hypertension 1 4 264 277 doi 10 1016 j jash 2007 04 004 PMID 20409858 Gao D Ning N Niu X Wei J Sun P Hao G May 2011 Aliskiren vs angiotensin receptor blockers in hypertension meta analysis of randomized controlled trials Am J Hypertens 24 5 613 21 doi 10 1038 ajh 2011 3 PMID 21293386 a b c d Staessen J A Li Y Richart T 2006 Oral renin inhibitors The Lancet 368 9545 1449 1456 doi 10 1016 S0140 6736 06 69442 7 PMID 17055947 S2CID 20729350 Umezawa H Aoyagi T Morishima H Matsuzaki M Hamada M Takeuchi T 1970 Pepstatin a new pepsin inhibitor produced by Actinomycetes The Journal of Antibiotics 23 5 259 262 doi 10 7164 antibiotics 23 259 PMID 4912600 Fisher N D L Hollenberg N K 2005 Renin Inhibition What Are the Therapeutic Opportunities Journal of the American Society of Nephrology 16 3 592 599 doi 10 1681 ASN 2004100874 PMID 15703270 Bonnevie O Svendsen L B Holst Christensen J Johansen T S Soltoft J Christiansen P M 1979 Double blind randomised clinical trial of a pepsin inhibitory pentapeptide pepstatin in the treatment of duodenal ulcer Gut 20 7 624 628 doi 10 1136 gut 20 7 624 PMC 1412504 PMID 385457 Svendsen L B Christiansen P M Bonnevie O 1979 Gastric ulcer therapy with a pepsin inactivating peptide pepstatin A double blind randomized clinical trial Scandinavian Journal of Gastroenterology 14 8 929 932 PMID 394302 Marciniszyn Jr J Hartsuck J A Tang J 1976 Mode of inhibition of acid proteases by pepstatin The Journal of Biological Chemistry 251 22 7088 7094 doi 10 1016 S0021 9258 17 32945 9 PMID 993206 Eid M Evin G Castro B Menard J Corvol P 1981 New renin inhibitors homologous with pepstatin The Biochemical Journal 197 2 465 471 doi 10 1042 bj1970465 PMC 1163147 PMID 7034718 Cumin F Evin G Fehrentz J A Seyer R Castro B Menard J et al 1985 Inhibition of human renin by synthetic peptides derived from its prosegment J Biol Chem 260 16 9154 9157 doi 10 1016 S0021 9258 17 39344 4 PMID 3894354 Szelke M Leckie B J Tree M Brown A Grant J Hallett A et al 1982 H 77 a potent new renin inhibitor In vitro and in vivo studies Hypertension 4 3 Pt 2 59 69 doi 10 1161 01 HYP 4 3 Pt 2 59 PMID 7040240 Tree M Atrash B Donovan B Gamble J Hallett A Hughes M Jones D M Leckie B Lever A F Morton J J Szelke M 1983 New inhibitors of human renin tested in vitro and in vivo in the anaesthetized baboon Journal of Hypertension 1 4 399 403 doi 10 1097 00004872 198312000 00013 PMID 6398331 Webb D J Manhem P J Ball S G Inglis G Leckie B J Lever A F Morton J J Robertson J I Murray G D Menard J Hallett A Jones D M Szelke M 1985 A study of the renin inhibitor H142 in man Journal of Hypertension 3 6 653 658 doi 10 1097 00004872 198512000 00013 PMID 3910726 Riccioni Graziano 2013 06 14 The role of direct renin inhibitors in the treatment of the hypertensive diabetic patient Therapeutic Advances in Endocrinology and Metabolism 4 5 SAGE Publications 139 145 doi 10 1177 2042018813490779 ISSN 2042 0188 PMC 3799297 PMID 24143271 Claude Cohen N 2007 Structure Based Drug Design and the Discovery of Aliskiren Tekturna Perseverance and Creativity to Overcome a R amp D Pipeline Challenge Chemical Biology amp Drug Design 70 6 557 565 doi 10 1111 j 1747 0285 2007 00599 x PMID 17999663 S2CID 221550002 a b Winiecka I Dudkiewicz Wilczynska J Roman I Paruszewski R 2010 New potential renin inhibitors with dipeptide replacements in the molecule Acta Poloniae Pharmaceutica 67 4 367 374 PMID 20635532 Gradman A H Kad R 2008 Renin inhibition in hypertension Review J Am Coll Cardiol 51 5 519 528 doi 10 1016 j jacc 2007 10 027 PMID 18237679 a b Lunney E A Hamilton H W Hodges J C Kaltenbronn J S Repine J T Badasso M Cooper J B Dealwis C Wallace B A Lowther W T 1993 Analyses of ligand binding in five endothiapepsin crystal complexes and their use in the design and evaluation of novel renin inhibitors Journal of Medicinal Chemistry 36 24 3809 3820 doi 10 1021 jm00076a008 PMID 8254610 Matter H Scheiper B Steinhagen H Bocskei Z Fleury V R McCort G 2011 Structure based design and optimization of potent renin inhibitors on 5 or 7 azaindole scaffolds Bioorganic amp Medicinal Chemistry Letters 21 18 5487 5492 doi 10 1016 j bmcl 2011 06 112 PMID 21840215 a b Yuan J Simpson R D Zhao W Tice C M Xu Z Cacatian S Jia L Flaherty P T Guo J Ishchenko A Wu Z McKeever B M Scott B B Bukhtiyarov Y Berbaum J Panemangalore R Bentley R Doe C P Harrison R K McGeehan G M Singh S B Dillard L W Baldwin J J Claremon D A 2011 Biphenyl diphenyl ether renin inhibitors Filling the S1 pocket of renin via the S3 pocket Bioorganic amp Medicinal Chemistry Letters 21 16 4836 4843 doi 10 1016 j bmcl 2011 06 043 PMID 21741239 a b Wood J M Maibaum J Rahuel J Grutter M G Cohen N C Rasetti V Ruger H Goschke R Stutz S Fuhrer W Schilling W Rigollier P Yamaguchi Y Cumin F Baum H P Schnell C R Herold P Mah R Jensen C O Brien E Stanton A Bedigian M P 2003 Structure based design of aliskiren a novel orally effective renin inhibitor Biochemical and Biophysical Research Communications 308 4 698 705 doi 10 1016 S0006 291X 03 01451 7 PMID 12927775 a b Politi A Durdagi S Moutevelis Minakakis P Kokotos G Mavromoustakos T 2010 Development of accurate binding affinity predictions of novel renin inhibitors through molecular docking studies Journal of Molecular Graphics and Modelling 29 3 425 435 doi 10 1016 j jmgm 2010 08 003 PMID 20855222 Akahane K Umeyama H Nakagawa S Moriguchi I Hirose S Iizuka K Murakami K 1985 Three dimensional structure of human renin Hypertension 7 1 3 12 doi 10 1161 01 hyp 7 1 3 PMID 3884499 Wu Y Shi C Sun X Wu X Sun H 2011 Synthesis biological evaluation and docking studies of octane carboxamide based renin inhibitors with extended segments toward S3 site of renin Bioorganic amp Medicinal Chemistry 19 14 4238 4249 doi 10 1016 j bmc 2011 05 059 PMID 21708467 Aliskiren containing Medications Drug Safety Comunication sic New Warning and Contraindication www fda gov Archived from the original on 2012 04 22 a b c Speedel Acquiring an additional 51 7 stake and announcing plans for mandatory public tender offer TRANSACTION OVERVIEW 2008 From Novartis http www novartis com downloads investors presentations events other events 2008 2008 07 speedel backgrounder pdf Tekturna HCT aliskiren hydrochlorothiazide tablets 2011 From US Food and Drug Administration http www accessdata fda gov drugsatfda docs label 2011 022107s009lbl pdfExternal links edit nbsp Wikimedia Commons has media related to renin inhibitors The Story of Aliskiren the first Renin Inhibitor drugdesign org Renin inhibitor aliskiren leads to dose dependent blood pressure reductions medicalnewstoday com Retrieved from https en wikipedia org w index php title Renin inhibitor amp oldid 1197769306, wikipedia, wiki, book, books, library,

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