How Your Body Regulates Blood Pressure with RAAS

January 1, 2021 by Ace Amino
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The renin-angiotensin-aldosterone system (RAAS) plays an important role in blood pressure regulation by regulating blood volume and systemic vascular resistance. There are three components to this system: 1) Renin, 2) Angiotensin, and 3) Aldosterone. Renin, which is primarily released by the kidneys, stimulates the formation of angiotensin 2 in blood and tissues, which in turn stimulates the release of aldosterone from the adrenal cortex.

Renin is an enzyme that is released into the circulation by the kidneys. Its release is stimulated by:

1) Sympathetic nerve activation,  2) Renal artery hypotension (caused by systemic hypotension or renal artery stenosis), 3) Decreased sodium delivery to the distal tubules of the kidney.

Juxtaglomerular (JG) cells associated with the afferent arteriole entering the renal glomerulus are the primary site of renin storage and release. A reduction in afferent arteriole pressure causes the release of renin from the JG cells, whereas increased pressure inhibits renin release. Added to this, beta1-adrenoceptors located on the JG cells respond to sympathetic nerve stimulation to release renin. Specialized cells (macula densa) of distal tubules lie adjacent to the JG cells of the afferent arteriole. The macula densa senses the concentration of sodium and chloride ions in the tubular fluid. When sodium chloride (NaCl) is elevated in the tubular fluid, renin release is inhibited. In contrast, a reduction in tubular NaCl stimulates renin release by the JG cells. When afferent arteriole pressure is reduced, glomerular filtration decreases, and this reduces NaCl in the distal tubule. This serves as an important mechanism contributing to the release of renin when there is afferent arteriole hypotension, which can be caused by systemic hypotension or narrowing (stenosis) of the renal artery that supplies blood flow to the kidney.

When renin is released into the blood, it acts upon a circulating substrate, angiotensinogen, that undergoes proteolytic cleavage to form the decapeptide angiotensin I. Vascular endothelium, particularly in the lungs, has an enzyme, angiotensin converting enzyme (ACE), that cleaves off two amino acids to form the octapeptide, angiotensin II (AG2), although many other tissues in the body (heart, brain, vascular) also can form AG2.

AG2 has several very important functions:

  • Constricts resistance vessels thereby increasing systemic vascular resistance and arterial pressure
  • Stimulates sodium reabsorption at several renal tubular sites, thereby increasing sodium and water retention by the body
  • Acts on the adrenal cortex to release aldosterone, which in turn acts on the kidneys to increase sodium and fluid retention
  • Stimulates the release of vasopressin (antidiuretic hormone, ADH) from the posterior pituitary, which increases fluid retention by the kidneys
  • Stimulates thirst centers within the brain
  • Facilitates norepinephrine release from sympathetic nerve endings and inhibits norepinephrine re-uptake by nerve endings, thereby enhancing sympathetic adrenergic function
  • Stimulates vascular hypertrophy

Therapeutic manipulation of this pathway is very important in treating hypertension. Ace inhibitors, AG2 receptor blockers, Aldosterone receptor blockers for instance, are used to decrease arterial pressure, ventricular afterload, blood volume and hence ventricular preload, as well as inhibit and reverse cardiac and vascular hypertrophy.

Ace Amino