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Query: UNIPROT:P02794 (
ferritin
)
17,525
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The female sex steroid, progesterone, plays a central role in mammalian pregnancy by regulating crucial events in the uterus such as transformation of endometrium for implantation and maintenance of pregnancy. The hormone acts through its specific
nuclear receptor
and modulates the functions of target cells by controlling the synthesis of specific proteins. The identity of genes that are regulated by progesterone in the uterus during various phases of pregnancy, however, remains largely unknown. In this study, we employed a differential gene-screening method to identify the gene encoding ferritin heavy chain (FHC), a component of the multisubunit iron-binding protein
ferritin
, as being regulated by progesterone in the uterus. We observed that uterine expression of the FHC messenger RNAs (mRNAs) rose dramatically at the onset of pregnancy, coincident with the surge of progesterone. FHC expression continued at this elevated level throughout gestation when the progesterone concentration remained high. At term, FHC expression declined sharply as the progesterone concentration dropped. We localized FHC proteins exclusively in uterine stromal cells, a major site of action of progesterone during pregnancy. Administration of mifepristone, an antiprogestin, during the early stages of pregnancy abolished both FHC mRNA and protein expression, clearly suggesting a primary role of progesterone in the regulation of this gene. Consistent with this scenario, administration of progesterone to ovariectomized animals after a brief estrogen priming led to a marked (25-fold) induction of FHC mRNA in the uterus, whereas estrogen, dexamethasone, or dihydrotestosterone had no effect. Based on these results, we propose that FHC is a novel and useful marker to study progesterone-regulated events in the uterus during pregnancy.
...
PMID:Ferritin heavy chain is a progesterone-inducible marker in the uterus during pregnancy. 764 19
Agricultural pesticide runoff has been suspected as the cause of numerous fish kills in rivers throughout Prince Edward Island but the impact on the surrounding marine environment is unknown. Endosulfan, an organochlorine pesticide, is a potent neurotoxin and molt inhibitor used to combat the Colorado potato beetle however it has the potential to affect non-target organisms including the American lobster (Homarus americanus). Metamorphosis is a critical stage of development and the effects of contaminant exposure during this time are largely unknown in lobster. A 14day endosulfan exposure was performed to identify the effects on survival, development and gene expression in lobster larvae during metamorphosis; all of which were predicted to be negatively impacted. The higher endosulfan concentrations resulted in greater mortality and a significant increase in the number of days required to reach metamorphosis in surviving animals. A custom made H. americanus microarray was used for monitoring the changes in expression of 14,592 genes at the termination of the exposure. Genes with >1.5 fold change and identified as being significant at p<0.05 using one-way ANOVA were selected for further analysis. A total of 707 genes were identified as being significantly differentiated, however with only ~40% annotation of the array, the majority of these genes were unknown. Annotated genes of interest were involved in many processes: development, metabolism, immunity and oxidative stress response and gene regulation. Nine genes of interest (histone H1, farnesoic acid O-methyltransferase, cuticle protein, glutathione S-transferase, thioredoxin, NADH dehydrogenase, ecdysone
nuclear receptor
Fushi tarazu F1 (FTZ-F1),
ferritin
and ecdysone inducible protein E75 (EIP-E75)) were selected for RT-qPCR validation of the microarray results. The RT-qPCR method was more sensitive than the microarray yet detected similar expression patterns. The two highest endosulfan concentrations resulted in increased mortalities, developmental delays in reaching metamorphosis and significant changes in gene expression. This research provides a foundation for using microarray gene expression profiles as screening tools for exploring the impact of environmental contaminants on lobster.
...
PMID:Analysis of gene expression in Homarus americanus larvae exposed to sublethal concentrations of endosulfan during metamorphosis. 2404 15
Mounting evidence indicates that the lysosome-autophagy pathway plays a critical role in iron release from
ferritin
, the main iron storage cellular protein, hence in the distribution of iron to the cells. The recent identification of
nuclear receptor
co-activator 4 as the receptor for
ferritin
delivery to selective autophagy sheds further light on the understanding of the mechanisms underlying this pathway. The emerging view is that iron release from
ferritin
through the lysosomes is a general mechanism in normal and tumour cells of different tissue origins, but it has not yet been investigated in brain cells. Defects in the lysosome-autophagy pathway are often involved in the pathogenesis of neurodegenerative disorders, and brain iron homeostasis disruption is a hallmark of many of these diseases. However, in most cases, it has not been established whether iron dysregulation is directly involved in the pathogenesis of the diseases or if it is a secondary effect derived from other pathogenic mechanisms. The recent evidence of the crucial involvement of autophagy in cellular iron handling offers new perspectives about the role of iron in neurodegeneration, suggesting that autophagy dysregulation could cause iron dyshomeostasis. In this review, we recapitulate our current knowledge on the routes through which iron is released from
ferritin
, focusing on the most recent advances. We summarise the current evidence concerning lysosome-autophagy pathway dysfunctions and those of iron metabolism and discuss their potential interconnections in several neurodegenerative disorders, such as Alzheimer's, Parkinson's and Huntington's diseases; amyotrophic lateral sclerosis; and frontotemporal lobar dementia.
...
PMID:Iron and Neurodegeneration: Is Ferritinophagy the Link? 2646 57
Ferritin, an iron-storage protein, regulates cellular iron metabolism and oxidative stress. The
ferritin
structure is characterized as a spherical cage, inside which large amounts of iron are deposited in a safe, compact and bioavailable form. All ferritins readily catalyze Fe(II) oxidation by peroxides at the ferroxidase center to prevent free Fe(II) from participating in oxygen free radical formation via Fenton chemistry. Thus,
ferritin
is generally recognized as a cytoprotective stratagem against intracellular oxidative damage The expression of cytosolic ferritins is usually regulated by iron status and oxidative stress at both the transcriptional and post-transcriptional levels. The mechanism of
ferritin
-mediated iron recycling is far from clarified, though
nuclear receptor
co-activator 4 (NCOA4) was recently identified as a cargo receptor for
ferritin
-based lysosomal degradation. Cytosolic ferritins are heteropolymers assembled by H- and L-chains in different proportions. The mitochondrial ferritins are homopolymers and distributed in restricted tissues. They play protective roles in mitochondria where heme- and Fe/S-enzymes are synthesized and high levels of ROS are produced. Genetic
ferritin
disorders are mainly related to the L-chain mutations, which generally cause severe movement diseases. This review is focused on the biochemistry and function of mammalian intracellular
ferritin
as the major iron-storage and anti-oxidation protein.
...
PMID:Biochemistry of mammalian ferritins in the regulation of cellular iron homeostasis and oxidative responses. 3297 54
