Plasma disappearance of exogenous erythropoietin in mice under different experimental conditions.

Erythropoietin (EPO) is a glycoprotein hormone produced primarily in the kidneys and to a lesser extent in the liver that regulates red cell production. Most of the studies conducted in experimental animals to assess the role of EPO in the regulation of erythropoiesis were performed in mouse models. However, little is known about the in vivo metabolism of the hormone in this species. The present study was thus undertaken to measure the plasma tl/2 of radiolabeled recombinant human EPO (rh-EPO) in normal mice as well as in mice with altered erythrocyte production rates (EPR), plasma EPO (pEPO) titer, marrow responsiveness, red cell volume, or liver function. Adult CF-1 mice of both sexes were used throughout. For the EPO life-span studies, 30 mice in each experiment were intravenously injected with 600,000 cpm of 125l-rh-EPO and bled by cardiac puncture in groups of five every hour for 6 h. Trichloroacetic acid (TCA) was added to each plasma sample and the radioactivity in the precipitate measured in a gamma-counter. EPO, pEPO, marrow responsiveness, or red cell volume were altered by either injections of rh-EPO, 5-fluorouracil, or phenylhydrazine, or by bleeding, or red cell transfusion. Liver function was altered by CI4C administration. In the normal groups of mice, the estimated tl/2 was 182.75+/-14.4 (SEM) min. The estimated tl/2 of the other experimental groups was not significantly different from normal. These results, therefore, strongly suggest that the clearance rate of EPO in mice is not subjected to physiologic regulation and that pEPO titer can be really taken as the reflection of the EPO production rate, at least in the experimental conditions reported here.

Unexpected hypoxia-dependent erythropoietin secretion during experimental conditions not affecting tissue oxygen supply/demand ratio.

Although a great deal of evidence supports the hypothesis that plasma erythropoietin (EPO) levels of mammals are related to the oxygen supply to the tissues relative to their oxygen needs, several observation millitate against its inherent simplicity. This study presents our results obtained from in vivo experiments that suggest that hypoxia-dependent EPO production can be altered by conditions which apparently do not modify the tissue oxygen supply/demand ratio. Hypoxia-dependent EPO production rate (EPO-PR), derived from plasma EPO titers and plasma EPO half-lives, were estimated in both transfused-polycythemic and normocythemic mouse models subjected to different treatments. From calculations of the O2 carrying capacity of blood and body O2 consumption, it was assumed that the tissue supply/demand ratios were similar in both experimental and control mice of the same model at the time of induction of EPO production. The following observations were worth noting: (1) EPO-PRs in transfused polycythemic mice whose erythropoietic rates were stimulated by intermittent exposure to hypobaria (0.5 atm, 18 hr/day x 3 weeks), phenylhydrazine administration (40 mg/kg at weekly intervals x 3 weeks) or repeated rh-EPO injections (1500 U/kg 3 times a week x 3 weeks) before transfusion were more than five times high than in comparabily polycythemic mice whose erythropoietic rates were not stimulated previously; and (2) EPO-PR in response to hypobaric hypoxia was 2.08 times normal in normocythemic mice with cyclophosphamide (100 mg/kg) induced depression of erythropoiesis, and 0.33 times normal in normocythemic mice with rh-EPO (400 U/kg x 2) induced enhancement of erythropoiesis. Although the results obtained in polycythemic mice are difficult to explain, those from normocythemic mice suggest the existence of a feedback mechanism between EPO-responsive cells and EPO-producing cells. Both demonstrate the existence of experimental conditions in which modulation of the hypoxia-dependent expression of the EPO gene appears to occur. This modulation would be dependent on factors other than oxygen.

Enhanced Erythropoietin Response to Acute Hypoxemia in Mice with Pharmacological Depression of Erythropoiesis.

The recent report of a depression of stimulated production of erythropoietin (EPO) in mice with enhanced erythropoiesis suggests that unknown mechanism (s) other than hypoxia may be involved in the regulation of EPO formation. The present study was thus designed to investigate EPO production during acute hypoxemia in a mouse model in which the oxygen-carrying capacity of blood, the plasma EPO level, and the plasma EPO half-life were within normal values in spite of a marked depression of the red cell production rate (RCPR) induced by cyclophosphamide (CP) administration. Injection of 100 mg/Kg of the drug into adult female CF-1 mice that previously received 0.4 ml of packed red cells depressed markedly the 24-hour RBC 59Fe uptake without affecting the plasma immunoreactive EPO level and the plasma disappearance of 1251-labeled recombinant human EPO. The EPO production rate, calculated from the change in plasma EPO levels and the estimated EPO clearance rate, after 4 h of exposure to hypobaric air was about 2.8 times higher in mice with CP-induced inhibition of the RCPR than in mice with normal RCPR. The results support the hypothesis that the EPO production rate in mammals is not only related to the oxygen supply to the tissues relative to their oxygen needs (main stimulus) but also to the erythroid activity of the marrow (modulatory action).