Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0240066 (iron deficiency)
7,156 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

It is unclear whether running can affect iron stores. Results using the serum ferritin assay (SER FER) have been conflicting. Decreased red cell ferritin (RBC FER) values (< or = 4 ag/RBC) occur in iron depleted or inflammatory states. We compared the longitudinal changes of hemoglobin (Hb), SER FER, RBC FER, % saturation of total iron binding capacity (% sat TIBC), and daily dietary intake in 27 runners during a training program. These parameters were measured at days 0, 49 (range 48-52), and 115 (range 85-120). No significant changes occurred in the SER FER, % sat TIBC and Hb determinations throughout the study. Overall the RBC FER values trended down (mean values 11.7 ag/RBC to 7.7 ag/RBC; p = 0.06). Fifteen runners (56%) acquired RBC FER values in the iron deficient range (mean 6.8 ag/RBC to 2.4 ag/RBC; p < 0.05). These values differed significantly from the remaining 12 runners (mean 17.3 ag/RBC to 14.7 ag/RBC). The decline in RBC FER into the iron deficient range was primarily seen in a subset of runners who began with a RBC FER value < or = 10 ag/RBC (positive predictive value 0.79) and was independent of iron intake. We conclude that ferritin can be affected by running as recognized by the red cell ferritin assay. Moreover our results suggest that this decrease in red cell ferritin is likely a function of defective iron utilization rather than total body iron deficiency. A potential consideration is that this fall may occur as a result of repetitive running-associated injury and inflammation.
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PMID:The effect of running on serum and red cell ferritin. A longitudinal comparison. 755 22

Iron deficiency is among the most common nutritional disorders in plants. To cope with low iron supply, plants with the exception of the Gramineae increase the solubility and uptake of iron by inducing physiological and developmental alterations including iron reduction, soil acidification, Fe(II) transport and root-hair proliferation (strategy I). The chlorotic tomato fer mutant fails to activate the strategy I. It was shown previously that the fer gene is required in the root. Here, we show that fer plants exhibit root developmental phenotypes after low and sufficient iron nutrition indicating that FER acts irrespective of iron supply. Mutant fer roots displayed lower Leirt1 expression than wild-type roots. We isolated the fer gene by map-based cloning and demonstrate that it encodes a protein containing a basic helix-loop-helix domain. fer is expressed in a cell-specific pattern at the root tip independently from iron supply. Our results suggest that FER may control root physiology and development at a transcriptional level in response to iron supply and thus may be the first identified regulator for iron nutrition in plants.
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PMID:The tomato fer gene encoding a bHLH protein controls iron-uptake responses in roots. 1237 Apr 9

Iron mobilization responses are induced by low iron supply at transcriptional level. In tomato, the basic helix-loop-helix gene FER is required for induction of iron mobilization. Using molecular-genetic techniques, we analyzed the function of BHLH029, named FRU (FER-like regulator of iron uptake), the Arabidopsis thaliana homolog of the tomato FER gene. The FRU gene was mainly expressed in roots in a cell-specific pattern and induced by iron deficiency. FRU mutant plants were chlorotic, and the FRU gene was found necessary for induction of the essential iron mobilization genes FRO2 (ferric chelate reductase gene) and IRT1 (iron-regulated transporter gene). Overexpression of FRU resulted in an increase of iron mobilization responses at low iron supply. Thus, the FRU gene is a mediator in induction of iron mobilization responses in Arabidopsis, indicating that regulation of iron uptake is conserved in dicot species.
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PMID:FRU (BHLH029) is required for induction of iron mobilization genes in Arabidopsis thaliana. 1555 41

Root iron mobilization genes are induced by iron deficiency downstream of an unknown signaling mechanism. The FER gene, encoding a basic helix-loop-helix domain protein and putative transcription factor, is required for induction of iron mobilization genes in roots of tomato (Lycopersicon esculentum). To study upstream regulatory events of FER action, we examined the control of FER gene and FER protein expression in response to iron nutritional status. We analyzed expression of the FER gene and FER protein in wild-type plants, in mutant plants with defects in iron uptake regulation, and in 35S transgenic plants that overexpressed the FER gene. An affinity-purified antiserum directed against FER epitopes was produced that recognized FER protein in plant protein extracts. We found that the FER gene and FER protein were consistently down-regulated in roots after generous (100 mum, physiologically optimal) iron supply compared to low (0.1 mum) and sufficient (10 mum) iron supply. FER gene and FER protein expression were also occasionally down-regulated at sufficient compared to low iron supply. Analysis of FER protein expression in FER overexpression plants, as well as cellular protein localization studies, indicated that FER was down-regulated by high iron at the posttranscriptional level. The FER protein was targeted to plant nuclei and showed transcriptional activation in yeast (Saccharomyces cerevisiae). FER protein regulation in the iron accumulation mutant chloronerva indicated that FER protein expression was not directly controlled by signals derived from iron transport. We conclude that FER is able to affect transcription in the nucleus and its action is controlled by iron supply at multiple regulatory levels.
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PMID:Iron-mediated control of the basic helix-loop-helix protein FER, a regulator of iron uptake in tomato. 1569 40

AtbHLH29 of Arabidopsis, encoding a bHLH protein, reveals a high similarity to the tomato FER which is proposed as a transcriptional regulator involved in controlling the iron deficiency responses and the iron uptake in tomato. For identification of its biological functions, AtbHLH29 was introduced into the genome of the tomato FER mutant T3238fer mediated by Agrobacterium tumefaciencs. Transgenic plants were regenerated and the stable integration of AtbHLH29 into their genomes was confirmed by Southern hybridization. Molecular analysis demonstrated that expression of the exogenous AtbHLH29 of Arabidopsis in roots of the FER mutant T3238fer enabled to complement the defect functions of FER. The transgenic plants regained the ability to activate the whole iron deficiency responses and showed normal growth as the wild type under iron-limiting stress. Our transformation data demonstrate that AtbHLH29 is a functional ortholog of the tomato FER and can completely replace FER in controlling the effective iron acquisition in tomato. Except of iron, FER protein was directly or indirectly involved in manganese homeostasis due to that loss functions of FER in T3238fer resulted in strong reduction of Mn content in leaves and the defect function on Mn accumulation in leaves was complemented by expression of AtbHLH29 in the transgenic plants. Identification of the similar biological functions of FER and AtbHLH29, which isolated from two systematically wide-diverged "strategy I" plants, suggests that FER might be a universal gene presented in all strategy I plants in controlling effective iron acquisition system in roots.
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PMID:AtbHLH29 of Arabidopsis thaliana is a functional ortholog of tomato FER involved in controlling iron acquisition in strategy I plants. 1611 51

We evaluated the analytical performance of a new, commercial, fully automated immunoturbidimetric assay for the determination of ferritin [FER-Latex(X2)CN SEIKEN, Denka Seiken, Japan] in serum on the Olympus AU2700 analyzer. The new assay is a latex-enhanced turbidimetric immunoassay with an analysis time of 10 min. The linearity of the assay was confirmed up to 2505 pmol/L (R2=0.999). The detection limit and the functional sensitivity were both 4.5 pmol/L. The intra- and inter-assay imprecision (CV) at 67, 506, 2186 pmol/L was < 1.8% and < 2.5%, respectively. Verification of the traceability to a WHO standard (80/578) showed a recovery of 102.6% (target value 449 pmol/L). No hook effect was observed in samples containing up to 33,705 pmol/L. The assay showed good correlation with the Beckman Immage nephelometric system (r=0.999). Hemoglobin (< or = 9.8 g/L), total bilirubin (< or = 113 micromol/L), conjugated bilirubin (< or = 109 micromol/L) and rheumatoid factor (< or = 5.2x10(5) IU/L) did not interfere with the assay. The reference interval (2.5-97.5 percentile) was 72-521 pmol/L for men and 27-267 pmol/L for women. The reference interval in patients with anemia, malignant tumors and hemochromatosis was 5.6-52, 130-2436 and 1465-2903 pmol/L, respectively. On the basis of the receiver operating characteristic curve, the 90% sensitivity cut-off value to distinguish between patients with and without iron deficiency was 40 pmol/L. The new latex turbidimetric procedure for ferritin assay is an attractive alternative that avoids the need for dedicated instrumentation.
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PMID:Preliminary evaluation of the performance of a new, highly sensitive commercial immunoassay for serum ferritin determination. 1620 2

Our groups have previously identified in independent studies the gene At2g28160 as a central transcription factor that is required for up-regulation of iron deficiency responses in Arabidopsis roots. At2g28160 has been named in different ways in our previous studies, namely FRU=FER-LIKE REGULATOR OF IRON UPTAKE [M. Jakoby, H.Y. Wang, W. Reidt, B. Weisshaar, P. Bauer, FRU (BHLH029) is required for induction of iron mobilization genes in Arabidopsis thaliana, FEBS Lett. 577 (2004) 528-534], BHLH029 [M.A. Heim, M. Jakoby, M. Werber, C. Martin, B. Weisshaar, P.C. Bailey, The basic helix-loop-helix transcription factor family in plants: a genome-wide study of protein structure and functional diversity, Mol. Biol. Evol. 20 (2003) 735-747; Y.X. Yuan, J. Zhang, D.W. Wang, H.Q. Ling, AtbHLH29 of Arabidopsis thaliana is a functional ortholog of tomato FER involved in controlling iron acquisition in strategy I plants, Cell Res. 15 (2005) 613-621] or FIT1=Fe-DEFICIENCY-INDUCED TRANSCRIPTION FACTOR1 [E.P.Colangelo, M.L. Guerinot, The essential basic helix-loop-helix protein FIT1 is required for the iron deficiency response, Plant Cell 12 (2004) 3400-3412.] To avoid any confusion in the future we propose a common name for At2g28160 in Arabidopsis, namely FIT=FER-LIKE IRON DEFICIENCY-INDUCED TRANSCRIPTION FACTOR.
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PMID:FIT, the FER-LIKE IRON DEFICIENCY INDUCED TRANSCRIPTION FACTOR in Arabidopsis. 1746 30

Iron is an essential and commonly limited nutrient for plants. To increase the uptake of iron during times of low iron supply, plants, except the grasses, activate a set of physiological and morphological responses in their roots that include iron reduction, soil acidification, Fe(II) transport and proliferation of root hairs. It is not known how root cells sense and transduce the changes that occur after the onset of iron deficiency. This work presents evidence that nitric oxide (NO) is produced rapidly in the root epidermis of tomato plants (Solanum lycopersicum) that are grown in iron-deficient conditions. The scavenging of NO prevented iron-deficiency-induced upregulation of the basic helix-loop-helix transcription factor FER, the ferric-chelate reductase LeFRO1 and the Fe(II) transporter LeIRT1 genes. On the other hand, exogenous application of the NO donor S-nitrosoglutathione enhanced the accumulation of FER, LeFRO1 and LeIRT1 mRNA in roots of iron-deficient plants. The activity of the root ferric-chelate reductase and the proliferation of root hairs induced by iron deficiency were stimulated by NO supplementation and suppressed by NO scavenging. Nitric oxide was ineffective in inducing iron-deficiency responses in the tomato fer mutant, which indicates that the FER protein is necessary to mediate the action of NO. Furthermore, NO supplementation improved plant growth under low iron supply, which suggests that NO is a key component of the regulatory mechanisms that control iron uptake and homeostasis in plants. In summary, the results of this investigation indicate that an increase in NO production is an early response of roots to iron deprivation that contributes to the improvement of iron availability by (i) modulating the expression of iron uptake-related genes and (ii) regulating the physiological and morphological adaptive responses of roots to iron-deficient conditions.
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PMID:Nitric oxide accumulation is required for molecular and physiological responses to iron deficiency in tomato roots. 1789 45

Plants need to mobilize iron in the soil, and the basic helix-loop-helix transcription factor FER is a central regulator of iron acquisition in tomato roots. FER activity is controlled by iron supply. To analyse to what extent FER influences Fe-regulated protein expression, we investigated the root proteome of wild-type tomato, the fer mutant and a transgenic FER overexpression line under low-iron conditions versus sufficient and generous iron supply. The root proteomes were analysed by two-dimensional gel electrophoresis with three technical and three biological replicates. Statistical analysis identified 39 protein spots that were differentially regulated in selected pairwise comparisons of experimental conditions. Of these, 24 were correlated with expression clusters revealed by principal component analysis. The 39 protein spots were analysed by MALDI-TOF and nanoLC-MS/MS to deduce their possible functions. We investigated the functional representation in the identified expression clusters, and found that loss of FER function in iron-cultured plants mimicked an iron-deficiency status. The largest identified protein expression cluster was upregulated by iron deficiency and in the fer mutant. Two iron-regulated proteins required FER activity for induction by iron deficiency. Few proteins were suppressed by iron deficiency. The differentially expressed proteins belonged predominantly to the functional categories 'stress', 'redox regulation' and 'miscellaneous peroxidases'. Hence, we were able to identify distinct expression clusters of proteins with distinct functions.
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PMID:A proteomic study showing differential regulation of stress, redox regulation and peroxidase proteins by iron supply and the transcription factor FER. 1822 64

To know the root adjustment in response to iron deficiency, differentially displayed proteins in tomato roots of wild type and its iron uptake inefficient mutant T3238fer were analyzed by 2-DE and MALDI-TOF MS-based proteomic method under iron sufficiency and deficiency. Ninety-seven proteins were identified, 63 of them were classified in various metabolic pathways. About 40 proteins involved in starch degradation, TCA and ascorbate cycles were upregulated under iron deficiency and grouped in a network together with glycolysis, whereas proteins for fructose metabolism were decreased. Proteins involved in methionine synthesis, cell wall synthesis, mitochondria ATP synthesis, vacuole ATPase, HSP70/90, etc. also revealed enhanced expression under iron deficiency, while proteins about redox homeostasis, transcription factors, kinases, etc. showed diversified changes. The responses are closely associated with energy metabolism, organic acid formation, root morphological change, redox and sulfur homeostasis, and signal transduction, which enhance iron uptake, reutilization and other adaptive changes. Most of the proteins affected by iron deficiency and fer mutation showed similar effect on individual proteins or pathways, but the independent function of FER to iron deficiency were statistically indicated.
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PMID:Proteomic response to iron deficiency in tomato root. 1845 29


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