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. 1974 Jan;53(1):163–172. doi: 10.1172/JCI107534

Plasma Clearance Rates and Renal Clearance of 3H-labeled Cyclic AMP and 3H-labeled Cyclic GMP in the Dog

Lawrence Blonde 1,2, Robert E Wehmann 1,2, Alton L Steiner 1,2
PMCID: PMC301450  PMID: 4357610

Abstract

Previously, in an attempt to understand the mechanisms involved in the regulation of plasma cyclic nucleotides, we measured concentrations of adenosine 3′,5′-monophosphate (cAMP) and guanosine 3′,5′-monophosphate (cGMP) in plasma from selected blood vessels of anesthetized dogs. The observation that the renal venous plasma concentrations of both cyclic nucleotides were less than arterial concentrations suggested that the kidney might be an important site for the elimination of these compounds from plasma and prompted further investigation of the renal handling of these compounds.

Tracer doses of either [3H]cAMP or [3H]cGMP were administered to anesthetized dogs by constant intravenous infusion, and metabolic clearance rates were determined. Concentrations of endogenous cyclic nucleotide and of cyclic nucleotide radioactivity were measured in aortic and renal venous plasma as well as in urine. Renal venous plasma [3H]cGMP was 39% and [3H]cAMP was 65% of the concentration in arterial plasma. Endogenous cyclic nucleotide levels showed a similar relationship. The plasma clearance rates (PCR) were 271±27 ml/min (mean±SE) for cGMP and 261±17 for cAMP. The total kidney clearance (calculated as the renal plasma flow × renal cyclic nucleotide extraction ratio) accounted for 52±4% and 30±2% of the PCR for cGMP and cAMP, respectively. Only about two-thirds of the total kidney clearance of each cyclic nucleotide could be accounted for by urinary excretion, the remainder presumably being the result of renal metabolism.

The urinary clearances of 3H-labeled cGMP (40.9±4.2 ml/min) and endogenous cGMP (45.0±2.3 ml/min) were not significantly different from each other. Both were approximately 50% greater than the glomerular filtration rate, which was 27.1±2.0 ml/min, indicating that a significant amount of urinary cGMP is derived from plasma by tubular secretion.

In contrast, the urinary clearances of 3H-labeled cAMP (23.7±1.9 ml/min) and endogenous cAMP (27.2±2.6 ml/min) were nearly equal both to each other and to the glomerular filtration rate, which was 24.6±1.7 ml/min. Thus, in the dog, glomerular filtration of plasma cAMP appears to be responsible for most of the cAMP found in urine. Renla production of cAMP, which in humans contributes from a third to a half of the urinary cAMP, was quantitatively of minor importance in the dog.

Thus, under the conditions of these experiments in dogs, renal elimination appears to be responsible for half of the PCR of cGMP and about a third of the PCR of cAMP. About a third of the renal elimination of both cyclic nucleotides appears to be due to metabolic degradation within the kidney, and the balance is due to excretion in the urine.

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Selected References

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