Physiological evolution of the renin-angiotensin system.

The renin-angiotensin system (RAS) in mammals may participate in the controls of blood pressure and aldosterone secretion, and possibly in the regulation of renal function. It has been shown that renin release is controlled by:1) two intrarenal receptors, the renal arteriolar receptor and the macula densa; 2) the sympathetic nervous system; and 3) several humoral agents. Recent studies indicate interrelations between the RAS and renal prostaglandins and the kallikrein-kinin system. Comparative studies have revealed that renal renin and the juxtaglomerular (JG) cells emerged during the early evolution of bony fishes, wherease the macula densa evolved later in the vertebrate phylogney. Exogenously administered angiotensins and renin produce vasopressor actions in representative species of all vertebrate classes from elasmobranchs to mammals, and increase secreations of mineralocorticoids from the adrenal cortex (interrenal) in amphibians, repitles, and possibly in teleosts. Angiotensin causes glomerular diuresis in teleosts and lung-fishes, which may be ascribed to increased dorsal aortic pressure, while angiotensin may have both glomerular and tubular actions in some amphibians. Intracranial injection of angiotensin stimulates drinking in teleosts, repites, and birds, but not in amphibians. Hemorrage and acute hypotension are potent stimuli for causing renin release in an aglomerular teleost and a bird. When we consider this fact together with the anatomical evidence that the evolution of the JG cells precedes that of the macula densa, it appears that the RAS HAS EVOLVED WITH A CLOSE RELATIONSHIP TO BLOOD PRESSURE HOEMOSTASIS. On the other hand, there is no clear evidence that the RAS is activated in depleted teleosts and amphibians. Although the RAS appears to exert several functions in man and other mammals, some of them may be more important in primitive animals, while a similar function remains in mammals as a relic of the primitive system. Comparative approaches provide a perspective of biological history and unique experimental model that will eventually aid in understanding of the underlying mechanisms operating in mammals.