An oligopeptide, angiotensin is a hormone and a dipsogen. It is derived from the precursor molecule angiotensinogen, a serum globulin produced in the liver. Angiotensin was isolated in the late 1930s (first named 'angiotonin' or 'hypertensin', later renamed 'angiotensin' as a consensus by the 2 groups that independently discovered it[5]) and subsequently characterized and synthesized by groups at the Cleveland Clinic and Ciba laboratories.[6]
Angiotensinogen is an α-2-globulin synthesized in the liver[7] and is a precursor for angiotensin, but has also been indicated as having many other roles not related to angiotensin peptides.[8] It is a member of the serpin family of proteins, leading to another name: Serpin A8,[9] although it is not known to inhibit other enzymes like most serpins. In addition, a generalized crystal structure can be estimated by examining other proteins of the serpin family, but angiotensinogen has an elongated N-terminus compared to other serpin family proteins.[10] Obtaining actual crystals for X-ray diffractometric analysis is difficult in part due to the variability of glycosylation that angiotensinogen exhibits. The non-glycosylated and fully glycosylated states of angiotensinogen also vary in molecular weight, the former weighing 53 kDa and the latter weighing 75 kDa, with a plethora of partially glycosylated states weighing in between these two values.[8]
Angiotensinogen is also known as renin substrate. It is cleaved at the N-terminus by renin to result in angiotensin I, which will later be modified to become angiotensin II.[8][10] This peptide is 485 amino acids long, and 10 N-terminus amino acids are cleaved when renin acts on it.[8] The first 12 amino acids are the most important for activity.
Plasma angiotensinogen levels are increased by plasma corticosteroid, estrogen, thyroidhormone, and angiotensin II levels. In mice with a full body deficit of angiotensinogen, the effects observed were low newborn survival rate, stunted body weight gain, stunted growth, and abnormal renal development.[8]
Angiotensin I (CAS# 11128-99-7), officially called proangiotensin, is formed by the action of renin on angiotensinogen. Renin cleaves the peptide bond between the leucine (Leu) and valine (Val) residues on angiotensinogen, creating the decapeptide (ten amino acid) (des-Asp) angiotensin I. Renin is produced in the kidneys in response to renal sympathetic activity, decreased intrarenal blood pressure (<90mmHg systolic blood pressure[11] ) at the juxtaglomerular cells, dehydration or decreased delivery of Na+ and Cl- to the macula densa.[12] If a reduced NaCl concentration[13] in the distal tubule is sensed by the macula densa, renin release by juxtaglomerular cells is increased. This sensing mechanism for macula densa-mediated renin secretion appears to have a specific dependency on chloride ions rather than sodium ions. Studies using isolated preparations of thick ascending limb with glomerulus attached in low NaCl perfusate were unable to inhibit renin secretion when various sodium salts were added but could inhibit renin secretion with the addition of chloride salts.[14] This, and similar findings obtained in vivo,[15] has led some to believe that perhaps "the initiating signal for MD control of renin secretion is a change in the rate of NaCl uptake predominantly via a luminal Na,K,2Cl co-transporter whose physiological activity is determined by a change in luminal Cl concentration."[16]
Angiotensin I appears to have no direct biological activity and exists solely as a precursor to angiotensin II.
Angiotensin I is converted to angiotensin II (AII) through removal of two C-terminal residues by the enzyme angiotensin-converting enzyme (ACE), primarily through ACE within the lung (but also present in endothelial cells, kidney epithelial cells, and the brain). Angiotensin II acts on the central nervous system to increase vasopressin production, and also acts on venous and arterial smooth muscle to cause vasoconstriction. Angiotensin II also increases aldosterone secretion; it therefore acts as an endocrine, autocrine/paracrine, and intracrine hormone.
ACE is a target of ACE inhibitor drugs, which decrease the rate of angiotensin II production. Angiotensin II increases blood pressure by stimulating the Gq protein in vascular smooth muscle cells (which in turn activates an IP3-dependent mechanism leading to a rise in intracellular calcium levels and ultimately causing contraction). In addition, angiotensin II acts at the Na+/H+ exchanger in the proximal tubules of the kidney to stimulate Na+ reabsorption and H+ excretion which is coupled to bicarbonate reabsorption. This ultimately results in an increase in blood volume, pressure, and pH.[17] Hence, ACE inhibitors are major anti-hypertensive drugs.
Angiotensin II is degraded to angiotensin III by angiotensinases located in red blood cells and the vascular beds of most tissues. Angiotensin II has a half-life in circulation of around 30 seconds,[18] whereas, in tissue, it may be as long as 15–30 minutes.
Angiotensin II results in increased inotropy, chronotropy, catecholamine (norepinephrine) release, catecholamine sensitivity, aldosterone levels, vasopressin levels, and cardiac remodeling and vasoconstriction through AT1 receptors on peripheral vessels (conversely, AT2 receptors impair cardiac remodeling). This is why ACE inhibitors and ARBs help to prevent remodeling that occurs secondary to angiotensin II and are beneficial in congestive heart failure.[16]
Angiotensin III, along with angiotensin II, is considered an active peptide derived from angiotensinogen.[19]
Angiotensin III has 40% of the pressor activity of angiotensin II, but 100% of the aldosterone-producing activity. Increases mean arterial pressure. It is a peptide that is formed by removing an amino acid from angiotensin II by glutamyl aminopeptidase A, which cleaves the N-terminal Asp residue.[20]
Activation of the AT2 receptor by angiotensin III triggers natriuresis, while AT2 activation via angiotensin II does not. This natriuretic response via angiotensin III occurs when the AT1 receptor is blocked.[21]
Angiotensin IV is a hexapeptide that, like angiotensin III, has some lesser activity. Angiotensin IV has a wide range of activities in the central nervous system.[22][23]
The exact identity of AT4 receptors has not been established. There is evidence that the AT4 receptor is insulin-regulated aminopeptidase (IRAP).[24] There is also evidence that angiotensin IV interacts with the HGF system through the c-Met receptor.[25][26]
The AT4 site may be involved in memory acquisition and recall, as well as blood flow regulation.[27] Angiotensin IV and its analogs may also benefit spatial memory tasks such as object recognition and avoidance (conditioned and passive avoidance).[28] Studies have also shown that the usual biological effects of angiotensin IV on the body are not affected by common AT2 receptor antagonists such as the hypertension medication Losartan.[28]
Angiotensins II, III and IV have a number of effects throughout the body:
Adipic
Angiotensins "modulate fat mass expansion through upregulation of adipose tissue lipogenesis ... and downregulation of lipolysis."[29]
Cardiovascular
Angiotensins are potent direct vasoconstrictors, constricting arteries and increasing blood pressure. This effect is achieved through activation of the GPCR AT1, which signals through a Gq protein to activate phospholipase C, and subsequently increase intracellular calcium.[30]
Angiotensin II has prothrombotic potential through adhesion and aggregation of platelets and stimulation of PAI-1 and PAI-2.[31][32]
Angiotensin II acts on the adrenal cortex, causing it to release aldosterone, a hormone that causes the kidneys to retain sodium and lose potassium. Elevated plasma angiotensin II levels are responsible for the elevated aldosterone levels present during the luteal phase of the menstrual cycle.
Renal
Angiotensin II has a direct effect on the proximal tubules to increase Na+reabsorption. It has a complex and variable effect on glomerular filtration and renal blood flow depending on the setting. Increases in systemic blood pressure will maintain renal perfusion pressure; however, constriction of the afferent and efferent glomerular arterioles will tend to restrict renal blood flow. The effect on the efferent arteriolar resistance is, however, markedly greater, in part due to its smaller basal diameter; this tends to increase glomerular capillary hydrostatic pressure and maintain glomerular filtration rate. A number of other mechanisms can affect renal blood flow and GFR. High concentrations of Angiotensin II can constrict the glomerular mesangium, reducing the area for glomerular filtration. Angiotensin II is a sensitizer to tubuloglomerular feedback, preventing an excessive rise in GFR. Angiotensin II causes the local release of prostaglandins, which, in turn, antagonize renal vasoconstriction. The net effect of these competing mechanisms on glomerular filtration will vary with the physiological and pharmacological environment.
Direct Renal effects of angiotensin II (not including aldosterone release)
^Kirchner KA, Kotchen TA, Galla JH, Luke RG (November 1978). "Importance of chloride for acute inhibition of renin by sodium chloride". The American Journal of Physiology. 235 (5): F444–50. doi:10.1152/ajprenal.1978.235.5.F444. PMID31796.
^Kim SM, Mizel D, Huang YG, Briggs JP, Schnermann J (May 2006). "Adenosine as a mediator of macula densa-dependent inhibition of renin secretion". American Journal of Physiology. Renal Physiology. 290 (5): F1016–23. doi:10.1152/ajprenal.00367.2005. PMID16303857. S2CID270730.
^ abSchnermann JB, Castrop H (2013). "Function of the Juxtaglomerular Apparatus". In Alpern RJ, Moe OW, Caplan M (eds.). Seldin and Giebisch's the Kidney (Fifth ed.). Academic Press. pp. 757–801. doi:10.1016/B978-0-12-381462-3.00023-9. ISBN978-0-12-381462-3.
^Le T (2012). First Aid for the Basic Sciences. Organ Systems. McGraw-Hill. p. 625.
^Patel P, Sanghavi D, Morris DL, Kahwaji CI (2023). "Angiotensin II". StatPearls. Treasure Island (FL): StatPearls Publishing. PMID29763087.
^Padia SH, Howell NL, Siragy HM, Carey RM (March 2006). "Renal angiotensin type 2 receptors mediate natriuresis via angiotensin III in the angiotensin II type 1 receptor-blocked rat". Hypertension. 47 (3): 537–544. doi:10.1161/01.HYP.0000196950.48596.21. PMID16380540. S2CID37807540.
^Chai SY, Fernando R, Peck G, Ye SY, Mendelsohn FA, Jenkins TA, Albiston AL (November 2004). "The angiotensin IV/AT4 receptor". Cellular and Molecular Life Sciences. 61 (21): 2728–2737. doi:10.1007/s00018-004-4246-1. PMID15549174. S2CID22816307.
^Wright JW, Harding JW (2015-01-01). "The Brain Hepatocyte Growth Factor/c-Met Receptor System: A New Target for the Treatment of Alzheimer's Disease". Journal of Alzheimer's Disease. 45 (4): 985–1000. doi:10.3233/JAD-142814. PMID25649658.
^ abWright JW, Kawas LH, Harding JW (February 2015). "The development of small molecule angiotensin IV analogs to treat Alzheimer's and Parkinson's diseases". Progress in Neurobiology. 125: 26–46. doi:10.1016/j.pneurobio.2014.11.004. PMID25455861. S2CID41360989.
^Wright JW, Krebs LT, Stobb JW, Harding JW (January 1995). "The angiotensin IV system: functional implications". Frontiers in Neuroendocrinology. 16 (1): 23–52. doi:10.1006/frne.1995.1002. PMID7768321. S2CID20552386.
^Gross PM, Wainman DS, Shaver SW, Wall KM, Ferguson AV (March 1990). "Metabolic activation of efferent pathways from the rat area postrema". The American Journal of Physiology. 258 (3 Pt 2): R788-97. doi:10.1152/ajpregu.1990.258.3.R788. PMID2316724.
^Boulpaep EL, Boron WF (2005). Medical Physiology: a Cellular and Molecular Approach. St. Louis, Mo: Elsevier Saunders. p. 771. ISBN978-1-4160-2328-9.
Further reading
de Gasparo M, Catt KJ, Inagami T, Wright JW, Unger T (September 2000). "International union of pharmacology. XXIII. The angiotensin II receptors". Pharmacological Reviews. 52 (3): 415–72. PMID10977869.
Brenner & Rector's The Kidney, 7th ed., Saunders, 2004.
Mosby's Medical Dictionary, 3rd Ed., CV Mosby Company, 1990.
Review of Medical Physiology, 20th Ed., William F. Ganong, McGraw-Hill, 2001.
Clinical Physiology of Acid-Base and Electrolyte Disorders, 5th ed., Burton David Rose & Theodore W. Post McGraw-Hill, 2001
Lees KR, MacFadyen RJ, Doig JK, Reid JL (August 1993). "Role of angiotensin in the extravascular system". Journal of Human Hypertension. 7 (Suppl 2): S7-12. PMID8230088.
Berry C, Touyz R, Dominiczak AF, Webb RC, Johns DG (December 2001). "Angiotensin receptors: signaling, vascular pathophysiology, and interactions with ceramide". American Journal of Physiology. Heart and Circulatory Physiology. 281 (6): H2337-65. doi:10.1152/ajpheart.2001.281.6.H2337. PMID11709400. S2CID41296327.
Varagic J, Frohlich ED (November 2002). "Local cardiac renin-angiotensin system: hypertension and cardiac failure". Journal of Molecular and Cellular Cardiology. 34 (11): 1435–42. doi:10.1006/jmcc.2002.2075. PMID12431442.
Wolf G (2006). "Role of reactive oxygen species in angiotensin II-mediated renal growth, differentiation, and apoptosis". Antioxidants & Redox Signaling. 7 (9–10): 1337–45. doi:10.1089/ars.2005.7.1337. PMID16115039.
Ariza AC, Bobadilla NA, Halhali A (2007). "[Endothelin 1 and angiotensin II in preeeclampsia]". Revista de Investigacion Clinica. 59 (1): 48–56. PMID17569300.
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