adrenomedullin and Anemia

Levels of adrenomedullin (AM) have been shown to be elevated in hypertension and chronic renal failure, suggesting that AM plays a role in the pathogenesis of these diseases. The objective of the present study was to investigate whether circulating AM is involved in erythropoietin (Epo)-induced hypertension in patients with renal anemia due to progressive renal disease. Following treatment with 6,000 IU of Epo once a week, the hematocrit (Ht) rose significantly from 25.9+/-4.0 to 33.4+/-3.3% (n=54, p<0.001) with an overall rate of increase in Ht of 0.43+/-0.04%/week. In response to treatment with Epo, a rise in mean blood pressure of >10 mmHg (Epo-induced hypertension) was found in 22% (12/54 cases) of the patients enrolled. There was no difference in the rate of Ht increase between patients with and without Epo-induced hypertension. There was a significant positive correlation between mature AM and serum creatinine (Cr) concentration before treatment with Epo. However, no correlation was found between the plasma concentration of total AM and serum Cr concentration. Long-term treatment with Epo did not influence plasma concentration of either mature AM or total AM in patients developing hypertension during the study period. These results suggest that circulating AM may play a role in the progression of renal disease. However, the present study does not support the notion that circulating AM is associated with the pathogenesis of Epo-induced hypertension. It is too early yet to claim that there is no AM-mediated mechanism in Epo-induced hypertension.

Topics: Adrenomedullin; Adult; Aged; Anemia; Creatinine; Erythropoietin; Hematocrit; Humans; Hypertension; Kidney Failure, Chronic; Middle Aged; Peptides

To investigate regional aspects of hypoxic regulation of adrenomedullin (AM) in kidneys, we mapped the distribution of AM in the rat kidney after hypoxia (normobaric hypoxic hypoxia, carbon monoxide, and CoCl(2) for 6 h), anemia (hematocrit lowered by bleeding) and after global transient ischemia for 1 h (unilateral renal artery occlusion and reperfusion for 6 and 24 h) and segmental infarct (6 and 24 h). AM expression and localization was determined in normal human kidneys and in kidneys with arterial stenosis. Hypoxia stimulated AM mRNA expression significantly in rat inner medulla (CO 13 times, 8% O(2) 6 times, and CoCl(2) 8 times), followed by the outer medulla and cortex. AM mRNA level was significantly elevated in response to anemia and occlusion-reperfusion. Immunoreactive AM was associated with the thin limbs of Henle's loop, distal convoluted tubule, collecting ducts, papilla surface epithelium, and urothelium. AM labeling was prominent in the inner medulla after CO and in the outer medulla after occlusion-reperfusion. The infarct border zone was strongly labeled for AM. In cultured inner medullary collecting duct cells, AM mRNA was significantly increased by hypoxia. AM mRNA was equally distributed in human kidney and AM was localized as in the rat kidney. In human kidneys with artery stenosis, AM mRNA was not significantly enhanced compared with controls, but AM immunoreactivity was observed in tubules, vessels, and glomerular cells. In summary, AM expression was increased in the rat kidney in response to hypoxic and ischemic hypoxia in keeping with oxygen gradients. AM was widely distributed in the human kidney with arterial stenosis. AM may play a significant role to counteract hypoxia in the kidney.

Topics: Adrenomedullin; Anemia; Animals; Cells, Cultured; Gene Expression; Humans; Hypertension, Renal; Hypoxia; Immunohistochemistry; Ischemia; Kidney; Male; Peptides; Rats; Rats, Sprague-Dawley; Renal Artery Obstruction; RNA, Messenger

Our study aimed to investigate the influence of tissue hypo-oxygenation on the adrenomedullin (ADM) system in vivo. For this purpose, male Sprague-Dawley rats were exposed to normobaric hypoxia (8% oxygen) or to functional anemia [0.1% carbon monoxide (CO)] or to cobalt chloride (60 mg/kg) for 6 h. Messenger RNA levels for ADM and its receptor (ADM-R) were assessed in diverse organs by RNase protection assay. Additionally, ADM protein concentrations in these organs, as in plasma, were determined by a RIA. We found that ADM mRNA abundance increased in response to hypoxia and to CO inhalation up to 15-fold in all organs examined. Similarly, ADM-R mRNA abundance increased during hypoxia and CO inhalation in all organs examined with exception of the liver. The effects of hypoxia and of CO inhalation on ADM and ADM-R mRNAs were mimicked by injection of cobaltous chloride. Hypoxia also significantly increased ADM protein content in all organs, and plasma levels of ADM rose twofold in response to hypoxia and CO inhalation. These findings indicate that tissue hypoxia leads to a widespread activation of the ADM system, which comprises a parallel stimulation of ADM and ADM receptor mRNA as enhanced ADM protein synthesis and secretion. The ADM system may, therefore, play a significant role in the physiological response to tissue hypoxia. It appears that ADM and ADM-R belong to the family of classic oxygen-regulated genes, which are activated by a decrease of the pericellular oxygen tension through the same intracellular signaling cascade.

Topics: Administration, Inhalation; Adrenomedullin; Anemia; Animals; Carbon Monoxide; Hypoxia; Male; Membrane Proteins; Oxygen Consumption; Peptides; Rats; Rats, Sprague-Dawley; Receptors, Adrenomedullin; Receptors, Peptide; RNA, Messenger; Tissue Distribution; Up-Regulation