Lipolysis-induced iron release from diferric transferrin: Possible role of lipoprotein lipase in LDL oxidation.

Conditions leading to oxidation of LDL in vivo are still unknown. While the occurrence of oxidized lipoproteins and catalytic free iron in advanced atherosclerotic lesions has been demonstrated, the origin of both is unclear. In vivo, iron metabolism is tightly regulated by iron-binding proteins that ensure that virtually no free iron exists. We examined whether physiological events such as lipolysis might reduce pH, facilitate iron release from transferrin (Tf), and promote low density lipoprotein (LDL) oxidation. Lipolysis is brought about by lipoprotein lipase (LpL), a triglyceride hydrolase present on endothelial cell surfaces and in atherosclerotic lesions. LpL hydrolysis of Intralipid lowered pH from 7.40 to 7.00 in 10% human serum and from 7.40 to 6.88 in phosphate-buffered saline. Similar decreases in pH were also observed when very low density lipoproteins were hydrolyzed by LpL. Lipolysis was accompanied by a 2-fold increase in the release of 59Fe from Tf. Tf binding to subendothelial matrix (SEM), a site of key events in atherosclerosis, increased 2-fold as the pH decreased from 7.40 to 6.00. More free iron also bound to SEM as the pH decreased below 7.40. We next tested whether a reduction in pH promotes LDL oxidation. More oxidation products were found in LDL incubated at low pH for 24 h in 10% human serum. Malonaldehyde contents (nmol/mg protein), measured as TBARS, were 7.11 +/- 0.34 at pH 7.40, 7.65 +/- 0.49 at pH 7.00, 9.00 +/- 1.18 at pH 6.50, and 11. 54 +/- 0.63 at pH 6.00.Based on these results, we hypothesize that lipolysis-induced acidic conditions enhance iron release from Tf and increase formation of oxidized LDL.     

Minimally modified low density lipoproteins induce aortic smooth muscle cell proliferation via the activation of mitogen activated protein kinase

We have investigated the effects of modifying LDL by Cu++ and various hemoglobin preparations on aortic smooth muscle cell proliferation and on the activation of mitogen activated protein kinase. We found that at very low concentrations (10 g/ml), LDL modified by all of the above agonists markedly stimulated cell proliferation (5–10 fold). This was accompanied by a 2–3 fold stimulation in mitogen activated protein kinase (MAPK) activity. We conclude that modification of LDL under situations that are closer to those found in vivo (i.e. hypoxic conditions), may involve the activation of MAPK as a common biochemical mechanism of action. This in turn, contributes to aortic smooth muscle cell proliferation.     

Maze learning impairment is associated with stress hemopoiesis induced by chronic treatment of aged rats with human recombinant erythropoietin

Mean cell volume (MCV) of erythrocytes has been reported to increase with age in humans, and to be negatively correlated with memory performance in humans and rats. We evaluated hematological changes in 21-mo old male Fischer 344 rats undergoing a 3-mo twice weekly subcutaneous injection of human recombinant erythropoietin (EPO). A baseline hematocrit (HCT) was obtained initially and repeated at monthly intervals to determine the effectiveness of EPO treatment. At 24-mo of age and after 3 mo EPO treatment, the rats were tested for their ability to learn a 14-unit T maze. Following maze testing, blood was drawn for hematologic analyses, including HCT, MCV, maximum swollen cell volume (MCVS), mean cell transit time (MCTT), and the membrane shear modulus of elasticity (G), the latter a derived measure of the relative elasticity of the red cell membrane. After 1 mo EPO treatment, HCT significantly increased compared to saline-injected controls. After 2 mo treatment, HCT began to decline but remained elevated above baseline levels even after 3 mo treatment. After 3 mo EPO treatment, MCV was significantly lower in EPO-treated rats compared to controls. These changes imply altered hemopoiesis to produce cells which undergo shrinkage associated with accelerated cellular aging. The lower MCV would have predicted a shorter MCTT which instead was unchanged. This observation suggested the presence of an additional factor contributing to the MCTT. The G, which measures the membrane contribution to deformability, very significantly increased with EPO treatment. This finding indicates an increased contribution of membrane properties to the MCTT after EPO treatment, which cancels the expected decrease in MCTT for smaller cells. After 3 mo of EPO treatment, aged rats exhibited significantly impaired maze learning compared to controls. A relationship between, changes in erythrocyte membrane properties and impaired function was indicated by a significant correlation (r=0.67, p <0.04) between G and errors in the 14-unit T-maze. These findings suggest that stress-induced erythropoiesis produces accelerated aging in the red blood cell population that may have functional implications (i.e., impaired learning ability).