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Query: UMLS:C0002871 (
anemia
)
52,094
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
A model is proposed for the role of the kidney in the control of erythropoietin production in which the initial trigger is an oxygen deficit created by
anemia
, hypobaria or ischemia. It is postulated that hypoxia creates a decrease in the oxygen level in a critical renal sensor cell, perhaps in the glomerular tuft, which eventually leads to the production of prostacyclin. It is possible that the endothelial cell in the glomerular tuft responds to this oxygen deficit to produce prostacyclin to trigger erythropoietin production. Recent studies on prostaglandin synthesis by human isolated glomeruli indicate that the most abundant prostanoid synthesized by the glomerular tuft cells was 6-keto PGF1 alpha, a metabolite of prostacyclin (PGI2). PGI2 has also been reported to be produced by isolated vascular endothelial cells. The mechanism by which hypoxia may initiate the synthesis and/or release of prostaglandins and prostacyclin in the renal cell has not been elucidated. Significant to erythropoietin production is the production by hypoxia of prostacyclin which eventually leads to the production of the metabolite
6-keto PGE1
. We further propose that
6-keto PGE1
is the prostanoid which activates a specific cell membrane adenylate cyclase, causing the conversion of ATP to cyclic AMP. This is a very critical step in that there must be a sufficient amount of ATP remaining to generate cyclic AMP in order for erythropoietin biosynthesis to occur with the reduced level of ATP which may have caused a perturbation of the cell membrane. The elevated cyclic AMP leads to the activation of protein kinases which are essential in phosphorylating the lysosomal hydrolases released by hypoxia into the cytosol of the cell and may be the precursors of erythropoietin. Neutral proteases and lysosomal hydrolases, documented triggers of erythropoietin production, have been demonstrated to be elevated in the kidney after hypoxia. The mechanism of labilization and release of these enzymes from the renal lysosomes has been postulated to be related to increases in cyclic GMP levels in a renal cell. Hypoxia causes the release of renal lysosomal hydrolases which then undergo phosphorylation through activation by protein kinases following prostanoid stimulation of renal adenylate cyclase to generate cyclic AMP, resulting in increased biosynthesis of erythropoietin.
...
PMID:Prostanoid activation of erythropoiesis. 654 29
A model has been presented for the role of the kidney in the physiologic and pathophysiologic control of erythropoiesis. It is postulated that an oxygen deficit created by
anemia
or hypobaric hypoxia results in the release of prostacyclin and its metabolite
6-keto PGE1
, and the release of PGE2 with ischemic hypoxia. Prostacyclin, 6-keto-PGE1, or PGE2 activation of adenylate cyclase, an increase in cyclic AMP, activation of a protein kinase and the phosphorylation of hydrolases, which have been released from lysosomes by hypoxia, lead to increased biosynthesis of erythropoietin (Ep). The mechanism of labilization of lysosomes and the release of hydrolases from these cell organelles is postulated to be related to increases in cyclic GMP levels in a renal cell. An Ep-producing human renal carcinoma cell line grown in tissue culture has been demonstrated to produce significant amounts of PGE2. Meclofenamate, an inhibitor of prostaglandins synthesis, was found to inhibit in vitro production of PGE2, Ep, and dome formation in these renal carcinoma cells, giving support to our hypothesis that pathophysiologic production of Ep tumor cells depends upon prostaglandins production. An Ep-producing clone from this renal carcinoma cell line has been developed that contains low electron density (LED) cells after the cells reach confluency, which show a cytoplasm, with abundant and widely dilated endoplasmic reticulum, an oval nucleus, dispersed chromatin, and prominent nucleoli. These are the cells responsible for dome formation and Ep production. Non-EP-producing clones have also been produced from this renal carcinoma cell line, which did not produce domes even at high cell density and had a distinctly different cell type than the Ep-producing clone. Thus, it is postulated that prostacyclin (PGI2) and its metabolite
6-keto PGE1
play a significant role in hypoxic hypoxia stimulation of Ep production and PGE2 is involved in ischemic hypoxia and renal carcinoma cell production of Ep. A modulating effect of PGE2 and PGD2, the two primary bone marrow prostaglandins, has been proposed in Ep stimulation of the erythroid progenitor cell compartment (CFU-E and BFU-E).
...
PMID:Effects of prostaglandins on erythropoiesis. 654 52
