Increased lipid peroxidation in pregnant women after iron and vitamin C supplementation

Iron overload could promote the generation of free radicals and result in deleterious cellular damages. A physiological increase of oxidative stress has been observed in pregnancy. A routine iron supplement, especially a combined iron and vitamin C supplementation, without biological justifications (low hemoglobin [Hb] and iron stores) could therefore aggravate this oxidative risk. We investigated the effect of a daily combined iron supplementation (100 mg/d as fumarate) and vitamin C (500 mg/d as ascorbate) for the third trimester of pregnancy on lipid peroxidation (plasma TBARS), antioxidant micronutriments (Zn, Se, retinol, vitaminE, (β-carotene) and antioxidant metalloenzymes (RBC Cu-Zn SOD and Se-GPX). The iron-supplemented group (n=27) was compared to a control group (n=27), age and number of pregnancies matched. At delivery, all the women exhibited normal Hb and ferritin values. In the supplemented group, plasma iron level was higher than in the control group (26.90±5.52 mmol/L) and TBARs plasma levels were significantly enhanced (p<0.05) (3.62±0.36 vs 3.01±0.37 mmol/L). No significant changes were observed in plasma trace elements and red blood cell antioxidant metalloenzymes. Furthermore, the α-tocopherol plasma level was lowered in the iron-supplemented groups, suggesting an increased utilization of vitamin E. These data show that pharmalogical doses of iron, associated with high vitamin C intakes, can result in uncontrolled lipid peroxidation. This is predictive of adverse effects for the mother and the fetus. This study illustrates the potential harmful effects of iron supplementation when prescribed only on the assumption of anemia and not on the bases of biological criteria.     

Age‐Related Changes in Fatty Acids in Obese Offspring of Streptozotocin‐Induced Diabetic Rats

Objective: The long‐term effects of fetal hyperinsulinemia, time course of changes in liver and very‐low‐density lipoprotein (VLDL) lipid levels and fatty acid compositions were investigated in obese offspring of streptozotocin‐induced mildly diabetic rats. Research Methods and Procedures: Mild hyperglycemia in pregnant rats was induced by intraperitoneal injection of streptozotocin on day 5 of gestation. Control pregnant rats were injected with citrate buffer. Liver and VLDL lipids and fatty acids were analyzed in offspring at different ages. Results: At birth, obese pups had higher VLDL triglyceride levels, saturated fatty acids, and C20:4n‐6. They also had lower C18:2n‐6 proportions in VLDL triglycerides, phospholipids, and cholesteryl esters than controls pups. In 1‐month‐old male and female obese rats, VLDL and liver lipid amounts were similar to those in their respective controls; however, high levels of C18:2n‐6 and C20:4n‐6 were noted in liver and VLDL lipids. At the age of 2 months, liver and VLDL triglyceride levels were higher in obese females than in control females. Fatty acid abnormalities seen in obese rats included low C18:3n‐3 and high C22:6n‐3 proportions in liver triglycerides and phospholipids. At the age of 3 months, obese rats, both males and females, compared with control animals, had higher VLDL and hepatic lipids with reduced C20:4n‐6 levels and polyunsaturated/saturated fatty acids ratios in hepatic and VLDL triglycerides and phospholipids. Discussion: Fetal obesity, associated with alterations in VLDL lipid fatty acid composition, represents an important risk factor for adult obesity and diabetes.     

Fonction catabolique de l'épithélium mammaire

Summary The histochemical (iron, lipopigments, acid phosphatase, leucine aminopeptidase) and cytologic (lysosomes) changes occuring during pregnancy, lactation and involution of mouse, rat, rabbit, guinea-pig mammary glands are studied by light microscopy and electron microscopy.In all the animals examined, the mammary epithelium has an intracellular digestive system which is adapted to subserve two functions. The first one is the segregation of cytoplasmic components which often precedes cellular involution. The second one is the regulation of secretory processes in the non lactating glands. This digestion of endogenous materials results in the formation of various lytic bodies: dense bodies sometimes containing ferritin, vacuolated dense bodies with membranous residues, autophagic vacuoles. The lysosomes can give large complex dense bodies like lipofuscin pigments with or without ferritin.Leucine aminopeptidase which always disappears in the mouse mammary epithelium during lactation is not present in rat, rabbit, guinea-pig mammary epithelium. In these species only the vascular tissue contains the enzyme. This observation indicates that leucine aminopeptidase does not take care of the overproduction of secretory products in the non-lactating glands.Acid phosphatase is concentrated in secretory granules and in lytic bodies: multivesicular bodies, dense bodies with ferritin, vacuolated dense bodies, lipopigments. This enzyme constitutes probably a mechanism for controlling and triggering the destruction of the secretory material with no active elimination.The iron of the mammary epithelium appears in virgin mice older than 30 weeks and in mice, rats, rabbits, guinea-pigs during glandular cells involution. This is a catabolic iron located in lysosomes. Its amount depends upon the iron content of the milk and upon the competitive secretory and catabolic activities of the glandular cells. An explanation of iron disappearance during a second pregnancy and lactation is discussed.     

Inhibitory effects of anions and active site amino acid sequence of chicken liver L-2-hydroxyacid oxidase A, a member of the FMN-dependent α-hydroxyacid oxidizing enzyme family

Monocarboxylic acids with aliphatic chains were found to be mixed inhibitors of chicken liver L-2-hydroxyacid oxidase A when L-2-hydroxy-4-methylthiobutanoic acid was used as the substrate. The finding that the binding affinity of the enzyme for monocarboxylic acids was directly proportional to the number of carbon atoms in the chain strongly suggests that in addition to the electrostatic interaction due to the carboxyl moiety, hydrophobic forces may also be involved in the binding affinity of monocarboxylic acids to the enzyme's active site. Oxalate, a dicarboxylic acid, also resulted in a mixed-type inhibition of chicken liver L-2-hydroxyacid oxidase A, and, surprisingly, its binding affinity to the enzyme was found to be quite high as compared with monocarboxylic acids. This is probably due to the fact that the two carboxyl groups of oxalate give rise to electrostatic interactions with the positively charged side chains of two adjacent residues in the polypeptide chain. The inhibitory effects of other dicarboxylic acids was found to decrease as the number of carbon atoms in the chain increased. Oxamate was found however to be a novel type of potent inhibitor of the enzyme. All in all, these kinetic studies and the amino acid sequence determination in the active site region after limited proteolysis of the polypeptide chain definitely establish that chicken liver NADH/FMN containing L-2-hydroxyacid oxidase A is a member of the FMN-dependent α-hydroxyacid oxidizing enzyme family.     

Physiological relationship between the temperate phages lambda and phi80

Summary This work deals with the ability of phage 80 to provide defective mutants of with their missing functions. Functions Involved in Recombination. As shown by others, the Int mechanism of 80 cannot excise prophage . However, 80 efficiently excises recombinants from tandem dilysogens, using its Ter mechanism. Likewise, the nonspecific mechanism Red is interchangeable between 80 and . Maturation of DNA by 80. The Ter recombinants excised by 80 from tandem dilysogens are packaged into a 80 protein coat. This contrasts with the fact, already mentionned by Dove, that 80 is extremely inefficient for packaging phage superinfecting a -lysogen. The latter result is also found when the helper phage is a hybrid with the left arm of (80hy4 or 80hy41 — see Fig. 1). However, the maturation of the superinfecting is much more efficient if the 80hy used as a helper has the att-N region of (like 80hy1). Conversely a with the att-N region of 80 (hy6 — see Fig. 1) is packaged more efficiently by 80 or 80hy4 than by 80hy1. It is suggested that the maturation of chromosome superinfecting an immune cell requires a recombination with the helper phage. Vegetative Functions. Among the replicative functoons O and P, the latter only can be supplied by 80. That N mutants are efficiently helped by 80 does not tell that 80 provides the defective with an active N product; the chromosomes are simply packaged into a 80 coat. This shows that 80 is unable to switch on the late genes of . That neither 80 nor any of the 80hy tested can provide an active N product is shown in a more direct way by their complete failure to help N ^-r₁₄; this phage carries a polar mutation which makes the expression of genes O and P entirely N-dependant. The maturation of a N ^- by 80 contrasts with the fact that mutants affected in late genes (A, F or H) are not efficiently helped by 80. This suggests that the products coded by these genes are not interchangeable between 80 and , and that packaging of DNA into 80 coats is possible but inhibited when late proteins are present in the cell. Activation of the Late Genes. Among the im ₈₀ h ⁺ hybrids tested, only 80hy41 is able to switch on the late genes of a N defective mutant. This hybrid differs from the other hybrids studied here, by the fact that it has the Q-S-R region of (see Fig. 1). The results are consistant with the view that the product of Q gene is sufficient for activating the late genes of a DNA. N would thus control the expression of late genes only indirectly by controlling the expression of gene Q (Couturier & Dambly have independantly reached the same conclusion, 1970). Furthermore the failure of 80 and of the 80hy1 and 80hy4 to activate the late genes of would imply that these phages are unable to provide an Q product active on the chromosome Reciprocally, switches on the late genes of prophage 80hy41, but not of prophages 80hy1 and 80hy4. This suggests that the initiation of late genes expression takes place at a main specific site located in the Q-S-R region of the chromosome. The expression of the late genes would thus be sequential, and proceed through the left arm only when steaky ends cohere. Similar conclusions were reached independantly by Toussaint (1969) and by Herskowitz and Signer (1970).

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Ce travail a été réalisé dans le cadre du contrat d'association Euratom-U. L. B. 007-61-10 ABIB et avec l'aide du Fonds de la Recherche Fondamentale Collective.