The juxtaglomerular apparatus in the kidney is important in controlling extracellular fluid volume and renin release. The fluid load to the distal tubule is first sensed at the macula densa site via the entry of NaCl, through a Na, K, 2Cl co-transport mechanism. The next step is unclear, but there is recent evidence of an increased macula densa cell calcium concentration with a reduction in fluid load to the macula densa. An increase in macula densa cell calcium could activate phospholipase A2 to release arachidonic acid, the rate-limiting step in the formation of prostaglandins. Recent evidence suggests that the prostaglandin formed is PGE2, a potent stimulator for renin release. Recent evidence has also shown that adenosine has an important function in the juxtaglomerular apparatus. It stimulates calcium release in afferent arteriolar smooth muscle cells, leading to contraction of the afferent arteriole as part of the tubuloglomerular feedback mechanism, and inhibits renin release. Thus, renin release from the afferent arteriole is mediated partly through formation of PGE2, and partly through the reduction of adenosine formation that inhibits renin production.
The juxtaglomerular apparatus (JGA) has the very important functions of detecting the fluid flow rate to the distal tubule and thus controlling the glomerular filtration rate (GFR) (tubuloglomerular feedback mechanism [TGF]) and renin release from the afferent arteriole. In studies of the TGF it has been evident that the sensitivity of this mechanism can be reset. Volume expansion will reset it to a low sensitivity leading to a high GFR and urine excretion rate, while dehydration will sensitize the TGF mechanism, giving rise to a low GFR and low urine excretion rate. Furthermore, we have found that in animals that spontaneously develop hypertension there is initially a sensitization of the TGF, leading to a reduced GFR and urine excretion rate, with fluid volume retention in the body and a consequent rise in blood pressure. When the pressure is raised, the TGF characteristics are normalized. In the macula densa (MD) cells in the JGA, there is a large production of NO from neuronal NOS. This production continuously reduces TGF sensitivity and is apparently impaired in animals that spontaneously develop hypertension. When we added an nNOS inhibitor to the drinking water for several weeks while measuring blood pressure, we found an increase in blood pressure after 3-4 weeks of treatment. This effect was abolished by a high salt diet. From these investigations, it also appeared as if nNOS-derived NO inhibited renin release. Experiments have also indicated that NO may resensitize inhibited G-protein coupled purinergic receptors.
We propose that albumin interferes with arteriolar nitric oxide homeostasis, probably by scavenging nitric oxide intra-luminally. In this respect, albumin acts similarly to red blood cells in the circulation. The magnitude of the scavenging determines the effectiveness of autoregulation in the perfused preglomerular vessels. The scavenging properties of the perfusing fluid are important in setting operating levels of endothelial nitric oxide.
The tubuloglomerular feedback (TGF) mechanism is an important regulator of the glomerular filtration rate (GFR) and urine excretion rate. It operates by sensing the distal delivery of fluid at the macula densa site and adjusting the tone of the glomerular arterioles to control GFR. We found evidence that nitric oxide is an important modulator of the setting of the sensitivity of the TGF mechanism. Studies on adenosine A1 receptor deficient mice have shown that these animals lack the TGF response and have an increased renin release. These findings show the important role of adenosine as a mediator of the signal for the TGF mechanism and as an inhibitor of renin release.
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