Transferrin Insufficiency and Iron Overload in Follicular Fluid Contribute to Oocyte Dysmaturity in Infertile Women With Advanced Endometriosis.

Purpose: To screen out specific protein with different concentration in follicular fluid from advanced endometriosis and determine its direct effect on mouse oocytes matured in vitro. Methods: FF samples were obtained from 25 patients (EMS group, n = 15; control group, n = 10) to screen the differential proteins by using iTRAQ Labeling and 2D LC-MS. Transferrin (TRF) in was found significantly decreased in EMS group, which was verified using ELISA in enlarged FF samples (EMS group, n = 31; control group, n = 27). The contents of ferric ion in FFs were detected by ELISA and TRF saturations were calculated in two groups. Germinal vesicle (GV) oocytes of mouse were maturated in vitro interfered with the FFs in five groups, whose concentrations of TRF were modulated, and maturation in vitro rates were compared among groups. Results: The reduced concentration of TRF with three analogs and increased concentration of ferric ion were found in the FF of the EMS group (p < 0.05). The numerical values of TSAT was 54.8% in EMS group, indicating iron overload in the FF. The EMS-FF showed significantly decreased maturation in vitro rate (p < 0.05) of mouse oocytes, which was improved with the supplementation of TRF, compared with the control-FF. The effect was blocked by the TRF antibody (p < 0.05). Conclusions: Being aware of the relatively small sample size, our results possibly suggest that TRF insufficiency and iron overload in FF from advanced EMS contribute to oocytes dysmaturity, which may be a cause of EMS-related infertility.

Nitroprusside induces melanoma ferroptosis with serum supplementation and prolongs survival under serum depletion or hypoxia.

BACKGROUND: When proliferating tumor cells expand to areas distant from vascular sites, poor diffusion of oxygen and nutrients occur, generating a restrictive hypoxic gradient in which susceptible tumor cells die. The heterogeneous population surviving hypoxia and metabolic starvation include de-differentiated cancer stem cells (CSC), capable of self-renewing tumor-initiating cells (TICs), or those that divide asymmetrically to produce non-tumor-initiating differentiated (NTI-D) cell progeny. Under such restrictive conditions, both populations slowly proliferate, entering quiescence or senescence, when exiting from cell cycle progression. This may drive chemoresistance and tumor recurrence, since most anti-cancer treatments target rapidly proliferating cells. PURPOSE: Since persistent or additional stress may increase NTI-D cells conversion to TICs, we investigated whether nutrient depletion or hypoxia influence expression of tyrosinase, a crucial enzyme for melanin synthesis, and B16 melanoma survival, when exposed to iron-dependent cell death oxidative stress produced by the Fenton reaction, resembling ferroptosis. RESULTS: -a) proliferating B16 melanoma with 10% serum-supplementation (10%S) normoxically express hypoxia inducible factor 1α (HIF1α) but lose tyrosinase, in contrast to those transiently exposed to (SF) serum-free medium, in which both HIF1α and tyrosinase are co-expressed; b) in contrast to the resistance to SNP toxicity in (SF) cells with higher tyrosinase expression, those in (10%S) are killed by iron from nitroprusside/ferricyanide (SNP) irrespective of exogenous H2O2, in a reaction antagonized by the anti-oxidant and MEK inhibitor UO126; c) Moreover, under transient serum depletion, SNP cooperates with hypoxia (1.5% oxygen), prolonging B16 melanoma (SF) survival; d) the hypoxia mimetic CoCl2 inhibits proliferation-associated cyclin A, irrespective of SNP, in (10%S) cells or in transiently serum-depleted (SF) cells. However, only in the latter cells, CoCl2 but not SNP, induce loss of HIF1α and apoptosis-associated PARP cleavage; e) longer term adaptation to survive serum depletion, generates (SS) cells resistant to SNP toxicity, which aerobically co-express HIF1α and tyrosinase. In SS B16 melanoma, exogenous non-toxic 100 µM H2O2 super-induces the ratio of tyrosinase to HIF1α. However, co-treatment of SS-B16 cells with SNP plus exogenous H2O2, partly increases PARP cleavage by reciprocally decreasing tyrosinase expression. SIGNIFICANCE: - These results suggest that a phenotypic plasticity in response to depletion of nutrients and/or oxygen, helps decide whether melanoma cells undergo either death by ferroptosis, or resistance to it, when challenged by the same exogenous oxidative stress (iron ± H2O2).

H-ferritin is the major source of iron for oligodendrocytes.

There is a critical relationship between oligodendrocyte development, myelin production, and iron bioavailability. Iron deficiency leads to hypomyelination both in humans and animal models, and the neurological sequelae of hypomyelination are significant. Therefore, understanding molecular mechanisms of iron import into oligodendrocytes is necessary for devising effective strategies for iron supplementation. Although transferrin has been considered as an essential component of oligodendrocyte media in culture, oligodendrocytes in vivo lack transferrin receptors. We have established that receptors for H-ferritin (HF) exist on cells of oligodendroglial lineage and that uptake of extracellular HF by oligodendrocyte progenitors is via receptor mediated endocytosis. These data strongly argue that ferritin is a major source of iron for oligodendrocytes. In this study, we demonstrate that media deficient in transferrin results in loss of viability of oligodendrocyte progenitors in culture. Cell loss could be prevented by supplementing the media with HF. Moreover, the addition of extracellular HF stimulates development of oligodendrocyte progenitor cells (OPCs) by increasing expression of myelin basic protein (MBP) and olig2 proteins without increasing their proliferation. The effect of HF on the OPCs could be mimicked by addition of membrane permeable 3,5,5-trimethylhexanoyl ferrocene (TMH-Fe) as an iron source to the media, but not membrane-impermeable ferric ammonium citrate. Overall, therefore, our results demonstrate the importance of iron for OPCs viability and differentiation and identify extracellular HF as a critical source of iron for oligodendrocytes. Given that ferritin receptors, but not transferrin receptors can be demonstrated on oligodendrocytes in vivo, the delivery of iron to oligodendrocytes via ferritin may be the more biological relevant delivery system.

Molecular characterization of a case of atransferrinemia.

Hereditary atransferrinemia is a rare but instructive disorder that has previously been reported in only 8 patients in 6 families. It is characterized by microcytic anemia and by iron loading, and can be treated effectively by plasma infusions. We now report the first case known in the United States. We determined the sequences flanking the exons of the human transferrin gene and sequenced all of the exons and some of the flanking regions of the patient's DNA and that of her parents. The patient's DNA revealed a 10-base pair (bp) deletion, followed by a 9-bp insertion of a duplicated sequence. There was also a G-->C transversion at complementary DNA (cDNA) nt 1429, predicting that a proline was substituted for the alanine in amino acid position 477 (Ala 477 Pro). The latter mutation occurs at an evolutionarily highly conserved site; 704 control alleles were screened and this point mutation was not found. Each of the patient's transferrin genes contains one mutation, ie, the patient is a compound heterozygote for these mutations, because one was found in each of her parents. In addition to these mutations, which we regard to be causative in the patient's atransferrinemia, a silent polymorphism at cDNA 1572 G-->C was found in exon 13 as well as 2 previously unreported polymorphisms at IVS8 + 62 c-->t and IVS14-4 c-->a. The mutation in nt 1572 and that in intron 8 were common in the general population; the intron 14 mutation is rare.

Immunohistochemical analysis of transferrin receptor: regional and cellular distribution in the hypotransferrinemic (hpx) mouse brain.

The hypotransferrinemic (hpx) mouse mutant produces <1% of the normal circulating level of transferrin (Tf). Heterozygote animals of this strain (hpx/+) have approximately 50% of normal plasma Tf levels. In this study we examine the cellular and regional distribution of Tf receptor (Tf-R) in the brain of wild type, hpx/+ and mutant (hpx/hpx) mice. Also, using slot-blot (immunoblot) analysis, we describe the relative amount of Tf-R in brain microvessels of hpx/+ animals compared with wild type. Tf-R was seen primarily in neurons throughout the brains of wild type, hpx/+ and hpx/hpx animals. Gray matter areas immunoreacted more robustly than white matter areas. Oligodendrocytes and third ventricle tanycytes, both of which we have previously described as iron-positive, did not immunoreact for Tf-R. Tf-R immunohistochemical reaction in wild type, hpx/+ and hpx/hpx brains appeared similar. Immunoblot analysis of isolated cortical microvessels from wild type and hpx/+ animals revealed no upregulation of Tf-R expression in hpx/+ (relative to normal) despite a 50% decrease in circulating Tf levels. These results indicate that Tf-R is primarily expressed by neurons and that half normal levels of Tf (hpx/+) or transferrin supplementation (hpx/hpx) are apparently sufficient for normal expression and distribution of Tf-R. Because of the lack of circulating Tf, but unaltered Tf-R expression, hpx mice could serve as a model for delivery of therapeutic agents via the Tf/Tf-R system.