Ceruloplasmin (Cp), a multicopper ferroxidase, is expressed as both a secreted (sCp) plasma enzyme from the liver and a membrane-bound glycosylphosphatidylinositol-anchored (GPI-Cp) splice variant protein. Cp is thought to be essential for iron mobilization as selective iron overload occurs in aceruloplasminemia in humans and in Cp null mice. Dietary copper-deficient (CuD) rodents have near total loss of Cp activity, severe loss of Cp protein and develop anemia. Hepatic iron augmentation is often observed, suggesting that loss of Cp function may be correlated with anemia. The impact of CuD treatment on GPI-Cp has not previously been evaluated. Our hypothesis was that CuD rodents would have lower levels of GPI-Cp and this would correlate with higher tissue iron retention. In these studies, GPI-Cp was detected in purified membranes of multiple organs of rats and mice but not Cp -/- mice. Immunoreactive Cp protein was released with phosphatidylinositol phospholipase C treatment and expressed ferroxidase activity. Following perinatal and postnatal copper restriction, GPI-Cp was markedly lower in the spleen and modestly lower in the liver of CuD rats and mice, when compared with copper-adequate (CuA) rodents. However, spleen non-heme iron (NHI) was lower in CuD than CuA rats, and not different in CuD mice. Hepatic iron was higher only in CuD mice. Spleen and liver membranes of CuD rats expressed augmented levels of ferroportin, the iron efflux transporter, which may explain lower NHI content in the spleen of CuD rats despite a greater than 50% lower level of the multicopper ferroxidase GPI-Cp. Spleen and liver levels of GPI-Cp mRNA were not impacted in CuD rats, suggesting that turnover rather than biosynthesis may explain the lower steady-state levels of GPI-Cp following dietary copper restriction. Lower GPI-Cp did not correlate with tissue iron retention and thus the role, if any, of Cp in anemia of copper deficiency is unknown.
Ceruloplasmin (Cp) is a multicopper oxidase and the most abundant copper binding protein in vertebrate plasma. Loss of function mutations in humans or experimental deletion in mice result in iron overload consistent with a putative ferroxidase function. Prior work suggested plasma may contain multiple ferroxidases. Studies were conducted in Holtzman rats (Rattus novegicus), albino mice (Mus musculus), Cp -/-mice, and adult humans (Homo sapiens) to investigate the copper-iron interaction. Dietary copper-deficient (CuD) rats and mice were produced using a modified AIN-76A diet. Results confirmed that o-dianisidine is a better substrate than paraphenylene diamine (PPD) for assessing diamine oxidase activity of Cp. Plasma from CuD rat dams and pups, and CuD and Cp -/-mice contained no detectable Cp diamine oxidase activity. Importantly, no ferroxidase activity was detectable for CuD rats, mice, or Cp -/-mice compared to robust activity for copper-adequate (CuA) rodent controls using western membrane assay. Immunoblot protocols detected major reductions (60-90%) in Cp protein in plasma of CuD rodents but no alteration in liver mRNA levels by qRT-PCR. Data are consistent with apo-Cp being less stable than holo-Cp. Further research is needed to explain normal plasma iron in CuD mice. Reduction in Cp is a sensitive biomarker for copper deficiency.
Copper deficiency leads to anemia but the mechanism is unknown. Copper deficiency also leads to hypoferremia, which may limit erythropoiesis. The hypoferremia may be due to limited function of multicopper oxidases (MCO) hephaestin in enterocytes or GPIceruloplasmin in macrophages of liver and spleen whose function as a ferroxidase is thought essential for iron transfer out of cells. Iron release may also be limited by ferroportin (Fpn), the iron efflux transporter. Fpn may be lower following copper deficiency because of impaired ferroxidase activity of MCO. Fpn is also dependent on the liver hormone hepcidin as Fpn is degraded when hepcidin binds to Fpn. Anemia and hypoferremia both down regulate hepcidin by separate mechanisms. Current studies confirmed and extended earlier studies with copper-deficient (CuD) rats that suggested low hepicidin resulted in augmented Fpn. However, current studies in CuD dams failed to confirm a correlation that hepcidin expression was associated with low transferrin receptor 2 (TfR2) levels and also challenged the dogma that holotransferrin can explain the correlation with hepcidin. CuD dams exhibited hypoferremia, low liver TfR2, anemia in some rats, yet no depression in Hamp expression, the hepcidin gene. Normal levels of GDF-15, the putative erythroid cytokine that suppresses hepcidin, were detected in plasma of CuD and iron-deficient (FeD) dams. Importantly, FeD dams did display greatly lower Hamp expression. Normal hepcidin in these CuD dams is puzzling since these rats may need extra iron to meet needs of lactation and the impaired iron transfer noted previously.
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