Absorption of iron from recombinant human lactoferrin in young US women.

BACKGROUND: Lactoferrin is a major protein component of human milk, and it binds iron with high affinity. Because the human small intestine has receptors for lactoferrin, a role for it in iron absorption has been suggested. OBJECTIVE: The objective was to study the absorption of iron from extrinsically labeled purified recombinant human lactoferrin produced in rice and to compare it with the absorption of iron from ferrous sulfate. DESIGN: On 2 occasions 4 wk apart, healthy young women (n = 20) were fed a standardized meal supplemented in randomized order with 59Fe as lactoferrin or as ferrous sulfate. Ten subjects received lactoferrin that had been heat-treated, and 10 subjects received untreated lactoferrin. Iron absorption was measured in a whole-body counter after 14 and 28 d and also was measured by red blood cell incorporation after 28 d. RESULTS: The difference in whole-body iron absorption between heat-treated (24.6 +/- 20.8%; n = 10) and untreated (16.2 +/- 4.4%; n = 10) lactoferrin was not significant. The difference in whole-body iron absorption between the groups given lactoferrin (20.4 +/- 15.3%; n = 20) or ferrous sulfate (18.8 +/- 13.2%; n = 20) also was not significant. Serum ferritin and iron absorption were inversely correlated in subjects when they received either lactoferrin or ferrous sulfate, which suggested that iron is absorbed from the 2 sources by a similar mechanism. CONCLUSIONS: Iron is equally well absorbed from lactoferrin (whether heat-treated or untreated) and ferrous sulfate. Thus, iron provided by dietary lactoferrin is likely to be well utilized in human adults.

Iron absorption from soybean ferritin in nonanemic women.

BACKGROUND: Dietary ferritin, a protein cage around an iron mineral, is an underestimated source of bioavailable iron. Plant ferritin, the most common dietary ferritin, has not been studied. Iron from animal ferritin is absorbed as well as is iron from FeSO4 in women. OBJECTIVE: The objective was to examine iron absorption from purified soybean ferritin. DESIGN: Healthy, nonanemic women (n = 16) were fed a standardized meal (bagel, cream cheese, and apple juice) containing 1 microCi 59Fe/meal as FeSO4 or (extrinsically labeled) as iron-free soybean ferritin reconstituted with the high phosphate characteristic of plant ferritin (iron:phosphorus = 4:1). Iron-free, apo-soybean ferritin was prepared (with the use of thioglycolic acid and extensive dialysis) from purified ferritin. In a randomized crossover design, the other labeled meal, which contained FeSO4 or ferritin, was given after 4 wk. The subjects received 140 microg Fe as ferritin (2.5 mg) or as FeSO4. After 28 d, whole-body 59Fe and 59Fe in red blood cells were measured before and after dosing. RESULTS: There was no significant difference in whole-body iron absorption from soybean ferritin (29.9 +/- 19.8%) and that from FeSO4 (34.3 +/- 23.6%) or in iron absorption calculated from red blood cell incorporation (33.0 +/- 20.1% for soybean ferritin and 35.3 +/- 23.4% for FeSO4), which confirmed previous results with animal ferritin that was mineralized and labeled similarly. An inverse relation was observed between serum ferritin and iron absorption from both ferritin and FeSO4, which suggested that sensors regulating iron absorption respond similarly to iron provided as ferrous salts or as ferritin mineral. CONCLUSION: Iron from soybean ferritin is well absorbed and may provide a model for novel, utilizable, plant-based forms of iron for populations with a low iron status.

Phospholipase D overcomes cell cycle arrest induced by high-intensity Raf signaling.

Low level expression of an active Raf kinase results in a transformed phenotype; however, high intensity Raf signals block cell cycle progression. Phospholipase D (PLD) has been implicated in regulating cell cycle progression and PLD activity is elevated in Raf transformed cells. We report here that high intensity Raf signals reduce PLD activity and that elevated expression of either PLD1 or PLD2 prevents cell cycle arrest induced by high intensity Raf signals. Overexpression of either PLD1 or PLD2 also reversed increases in p21(Cip1) and protein kinase C delta (PKC delta) cleavage seen with high intensity Raf signals. These data indicate that PLD signaling provides a novel survival signal that overcomes cell cycle arrest induced by high intensity Raf signaling.