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Ferritin

October 14, 2023

Ferritin is a universal intracellular protein that stores iron and releases it in a controlled fashion. The protein is produced by almost all living organisms, including archaea, bacteria, algae, higher plants, and animals. It is the primary intracellular iron-storage protein in both prokaryotes and eukaryotes, keeping iron in a soluble and non-toxic form. In humans, it acts as a buffer against iron deficiency and iron overload.[3]

Ferritin
Structure of the murine ferritin complex[1]
Identifiers
SymbolFerritin
PfamPF00210
Pfam clanCL0044
InterProIPR008331
SCOP21fha / SCOPe / SUPFAM
Available protein structures:
Pfam  structures / ECOD  
PDBRCSB PDB; PDBe; PDBj
PDBsumstructure summary
ferritin, light polypeptide
Identifiers
SymbolFTL
NCBI gene2512
HGNC3999
OMIM134790
RefSeqNM_000146
UniProtP02792
Other data
LocusChr. 19 q13.3–13.4
Search for
StructuresSwiss-model
DomainsInterPro
ferritin, heavy polypeptide 1
Identifiers
SymbolFTH1
Alt. symbolsFTHL6
NCBI gene2495
HGNC3976
OMIM134770
RefSeqNM_002032
UniProtP02794
Other data
LocusChr. 11 q13
Search for
StructuresSwiss-model
DomainsInterPro
ferritin mitochondrial
Crystallographic structure of mitochondrial ferritin.[2]
Identifiers
SymbolFTMT
NCBI gene94033
HGNC17345
OMIM608847
RefSeqNM_177478
UniProtQ8N4E7
Other data
LocusChr. 5 q23.1
Search for
StructuresSwiss-model
DomainsInterPro

Ferritin is found in most tissues as a cytosolic protein, but small amounts are secreted into the serum where it functions as an iron carrier. Plasma ferritin is also an indirect marker of the total amount of iron stored in the body; hence, serum ferritin is used as a diagnostic test for iron-deficiency anemia.[4] Aggregated ferritin transforms into a toxic form of iron called hemosiderin.[5]

Ferritin is a globular protein complex consisting of 24 protein subunits forming a hollow nanocage with multiple metal–protein interactions.[6] Ferritin that is not combined with iron is called apoferritin.[citation needed]

Gene Edit

Ferritin genes are highly conserved between species. All vertebrate ferritin genes have three introns and four exons.[7] In human ferritin, introns are present between amino acid residues 14 and 15, 34 and 35, and 82 and 83; in addition, there are one to two hundred untranslated bases at either end of the combined exons.[8] The tyrosine residue at amino acid position 27 is thought to be associated with biomineralization.[9]

Protein structure Edit

Ferritin is a hollow globular protein of mass 474 kDa and comprising 24 subunits. Typically it has internal and external diameters of about 8 and 12 nm, respectively.[10] The nature of these subunits varies by class of organism:

All the aforementioned ferritins are similar, in terms of their primary sequence, with the vertebrate H-type.[11] In E. coli, a 20% similarity to human H-ferritin is observed.[11] Some ferritin complexes in vertebrates are hetero-oligomers of two highly related gene products with slightly different physiological properties. The ratio of the two homologous proteins in the complex depends on the relative expression levels of the two genes.

Inside the ferritin shell, iron ions form crystallites together with phosphate and hydroxide ions. The resulting particle is similar to ferrihydrite. Each ferritin complex can store about 4500 iron (Fe3+) ions.[8][11]

A human mitochondrial ferritin, MtF, was found to express as a pro-protein.[13] When a mitochondrion takes it up, it processes it into a mature protein similar to the ferritins found in the cytoplasm, which it assembles to form functional ferritin shells. Unlike other human ferritins, it appears to have no introns in its genetic code. An X-ray diffraction study has revealed that its diameter is 1.70 angstroms (0.17 nm), it contains 182 residues, and is 67% helical. The mitochondrial ferritin's Ramachandran plot[14] shows its structure to be mainly alpha helical with a low prevalence of beta sheets.

Function Edit

Iron storage Edit

 
Iron uptake through the 3-fold channel of ferritin

Ferritin is present in every cell type.[8] It serves to store iron in a non-toxic form, to deposit it in a safe form, and to transport it to areas where it is required.[15] The function and structure of the expressed ferritin protein varies in different cell types. This is controlled primarily by the amount and stability of messenger RNA (mRNA), but also by changes in how the mRNA is stored and how efficiently it is transcribed.[8] One major trigger for the production of many ferritins is the mere presence of iron;[8] an exception is the yolk ferritin of Lymnaea sp., which lacks an iron-responsive unit.[11]

Free iron is toxic to cells as it acts as a catalyst in the formation of free radicals from reactive oxygen species via the Fenton reaction.[16] Hence vertebrates have an elaborate set of protective mechanisms to bind iron in various tissue compartments[discuss]. Within cells, iron is stored in a protein complex as ferritin or the related complex hemosiderin. Apoferritin binds to free ferrous iron and stores it in the ferric state. As ferritin accumulates within cells of the reticuloendothelial system, protein aggregates are formed as hemosiderin. Iron in ferritin or hemosiderin can be extracted for release by the RE cells, although hemosiderin is less readily available. Under steady-state conditions, the level of ferritin in the blood serum correlates with total body stores of iron; thus, the serum ferritin FR5Rl is the most convenient laboratory test to estimate iron stores.[citation needed]

Because iron is an important mineral in mineralization, ferritin is employed in the shells of organisms such as molluscs to control the concentration and distribution of iron, thus sculpting shell morphology and colouration.[17][18] It also plays a role in the haemolymph of the polyplacophora, where it serves to rapidly transport iron to the mineralizing radula.[19]

Iron is released from ferritin for use by ferritin degradation, which is performed mainly by lysosomes.[20]

Ferroxidase activity Edit

Vertebrate ferritin consists of two or three subunits which are named based on their molecular weight: L "light", H "heavy", and M "middle" subunits. The M subunit has only been reported in bullfrogs. In bacteria and archaea, ferritin consists of one subunit type.[21] H and M subunits of eukaryotic ferritin and all subunits of bacterial and archaeal ferritin are H-type and have ferroxidase activity, which is the conversion of iron from the ferrous (Fe2+) to ferric (Fe3+) forms. This limits the deleterious reaction which occurs between ferrous iron and hydrogen peroxide known as the Fenton reaction which produces the highly damaging hydroxyl radical. The ferroxidase activity occurs at a diiron binding site in the middle of each H-type subunits.[21][22] After oxidation of Fe(II), the Fe(III) product stays metastably in the ferroxidase center and is displaced by Fe(II),[22][23] a mechanism that appears to be common among ferritins of all three kingdoms of life.[21] The light chain of ferritin has no ferroxidase activity but may be responsible for the electron transfer across the protein cage.[24]

Immune response Edit

Ferritin concentrations increase drastically in the presence of an infection or cancer. Endotoxins are an up-regulator of the gene coding for ferritin, thus causing the concentration of ferritin to rise. By contrast, organisms such as Pseudomonas, although possessing endotoxin, cause plasma ferritin levels to drop significantly within the first 48 hours of infection. Thus, the iron stores of the infected body are denied to the infective agent, impeding its metabolism.[25]

Stress response Edit

The concentration of ferritin has been shown to increase in response to stresses such as anoxia,[26] which implies that it is an acute phase protein.[27]

Mitochondria Edit

Mitochondrial ferritin has many roles pertaining to molecular function. It participates in ferroxidase activity, binding, iron ion binding, oxidoreductase activity, ferric iron binding, metal ion binding as well as transition metal binding. Within the realm of biological processes it participates in oxidation-reduction, iron ion transport across membranes and cellular iron ion homeostasis.[citation needed]

Yolk Edit

In some snails, the protein component of the egg yolk is primarily ferritin.[28] This is a different ferritin, with a different genetic sequence, from the somatic ferritin. It is produced in the midgut glands and secreted into the haemolymph, whence it is transported to the eggs.[28]

Tissue distribution Edit

In vertebrates, ferritin is usually found within cells, although it is also present in smaller quantities in the plasma.[25]

Diagnostic uses Edit

Serum ferritin levels are measured in medical laboratories as part of the iron studies workup for iron-deficiency anemia.[6] They are measured in nanograms per milliliter (ng/mL) or micrograms per liter (μg/L); the two units are essentially equivalent.

The ferritin levels measured usually have a direct correlation with the total amount of iron stored in the body. However, ferritin levels may be artificially high in cases of anemia of chronic disease, where ferritin is elevated in its capacity as an inflammatory acute phase protein and not as a marker for iron overload.[citation needed]

Normal ranges Edit

A normal ferritin blood level, referred to as the reference interval is determined by many testing laboratories. The ranges for ferritin can vary between laboratories but typical ranges would be between 40 and 300 ng/mL (=μg/L) for males, and 20–200 ng/mL (=μg/L) for females.[29]

Normal ferritin blood levels according to sex and age[citation needed]
Adult males 40–300 ng/mL (μg/L)[29]
Adult females 20–200 ng/mL (μg/L)[29]
Children (6 months to 15 years) 50–140 ng/mL (μg/L)
Infants (1 to 5 months) 50–200 ng/mL (μg/L)
Neonates 25–200 ng/mL (μg/L)

Deficiency Edit

According to a 2014 review in the New England Journal of Medicine stated that a ferritin level below 30 ng/mL indicates iron deficiency, while a level below 10 ng/mL indicates iron-deficiency anemia.[29] A 2020 World Health Organization guideline states that ferritin indicates iron deficiency below 12 ng/mL in apparently-healthy children under 5 and 15 ng/mL in apparently-healthy individuals of 5 and over.[30]

Some studies suggest that women with fatigue and ferritin below 50 ng/mL see reduced fatigue after iron supplementation.[31][32]

In the setting of anemia, low serum ferritin is the most specific lab finding for iron-deficiency anemia.[33] However it is less sensitive, since its levels are increased in the blood by infection or any type of chronic inflammation,[34] and these conditions may convert what would otherwise be a low level of ferritin from lack of iron, into a value in the normal range. For this reason, low ferritin levels carry more information than those in the normal range. A falsely low blood ferritin (equivalent to a false positive test) is very uncommon,[34] but can result from a hook effect of the measuring tools in extreme cases.[35]

Low ferritin may also indicate hypothyroidism, vitamin C deficiency or celiac disease.[citation needed]

Low serum ferritin levels are seen in some patients with restless legs syndrome, not necessarily related to anemia, but perhaps due to low iron stores short of anemia.[36][37]

Vegetarianism is not a cause of low serum ferritin levels, according to the American Dietetic Association's position in 2009: "Incidence of iron-deficiency anemia among vegetarians is similar to that of non-vegetarians. Although vegetarian adults have lower iron stores than non-vegetarians, their serum ferritin levels are usually within the normal range."[38]

Excess Edit

If ferritin is high, there is iron in excess or else there is an acute inflammatory reaction in which ferritin is mobilized without iron excess. For example, ferritins may be high in infection without signaling body iron overload.

Ferritin is also used as a marker for iron overload disorders, such as hemochromatosis or hemosiderosis. Adult-onset Still's disease, some porphyrias, and hemophagocytic lymphohistiocytosis/macrophage activation syndrome are diseases in which the ferritin level may be abnormally raised.

As ferritin is also an acute-phase reactant, it is often elevated in the course of disease. A normal C-reactive protein can be used to exclude elevated ferritin caused by acute phase reactions.[citation needed]

Ferritin has been shown to be elevated in some cases of COVID-19 and may correlate with worse clinical outcome.[39][40] Ferritin and IL-6 are considered to be possible immunological biomarkers for severe and fatal cases of COVID-19. Ferritin and C-reactive protein may be possible screening tools for early diagnosis of systemic inflammatory response syndrome in cases of COVID-19.[41][42]

According to a study of anorexia nervosa patients, ferritin can be elevated during periods of acute malnourishment, perhaps due to iron going into storage as intravascular volume and thus the number of red blood cells falls.[43]

Another study suggests that due to the catabolic nature of anorexia nervosa, isoferritins may be released. Furthermore, ferritin has significant non-storage roles within the body, such as protection from oxidative damage. The rise of these isoferritins may contribute to an overall increase in ferritin concentration. The measurement of ferritin through immunoassay or immunoturbidimeteric methods may also be picking up these isoferritins thus not a true reflection of iron storage status.[44]

Studies reveal that a transferrin saturation (serum iron concentration ÷ total iron binding capacity) over 60 percent in men and over 50 percent in women identified the presence of an abnormality in iron metabolism (hereditary hemochromatosis, heterozygotes, and homozygotes) with approximately 95 percent accuracy. This finding helps in the early diagnosis of hereditary hemochromatosis, especially while serum ferritin still remains low. The retained iron in hereditary hemochromatosis is primarily deposited in parenchymal cells, with reticuloendothelial cell accumulation occurring very late in the disease. This is in contrast to transfusional iron overload in which iron deposition occurs first in the reticuloendothelial cells and then in parenchymal cells. This explains why ferritin levels remain relative low in hereditary hemochromatosis, while transferrin saturation is high.[45][46]

In chronic liver diseases Edit

Hematological abnormalities often associate with chronic liver diseases. Both iron overload and iron deficient anemia have been reported in patients with liver cirrhosis.[47][48] The former is mainly due to reduced hepcidin level caused by the decreased synthetic capacity of the liver, while the latter is due to acute and chronic bleeding caused by portal hypertension. Inflammation is also present in patients with advanced chronic liver disease. As a consequence, elevated hepatic and serum ferritin levels are consistently reported in chronic liver diseases.[49][50][51]

Studies showed association between high serum ferritin levels and increased risk of short-term mortality in cirrhotic patients with acute decompensation[52] and acute-on-chronic liver failure.[53] An other study found association between high serum ferritin levels and increased risk of long-term mortality in compensated and stable decompensated cirrhotic patients.[54] The same study demonstrated that increased serum ferritin levels could predict the development of bacterial infection in stable decompensated cirrhotic patients, while in compensated cirrhotic patients the appearance of the very first acute decompensation episode showed higher incidence in patients with low serum ferritin levels. This latter finding was explaind by the association between chronic bleeding and increased portal pressure.[54]

Applications Edit

Ferritin is used in materials science as a precursor in making iron nanoparticles for carbon nanotube growth by chemical vapor deposition.

Cavities formed by ferritin and mini-ferritins (Dps) proteins have been successfully used as the reaction chamber for the fabrication of metal nanoparticles (NPs).[55][56][57][58] Protein shells served as a template to restrain particle growth and as a coating to prevent coagulation/aggregation between NPs. Using various sizes of protein shells, various sizes of NPs can be easily synthesized for chemical, physical and bio-medical applications.[6][59]

Experimental COVID-19 vaccines have been produced that display the spike protein's receptor binding domain on the surface of ferritin nanoparticles.[60]

Notes Edit

The primary sequence of human ferritin is MTTASTSQVR QNYHQDSEAA INRQINLELY ASYVYLSMSY YFDRDDVALK NFAKYFLHQS HEEREHAEKL MKLQNQRGGR IFLQDIKKPD CDDWESGLNA MECALHLEKN VNQSLLEFPS PISPSPSCWH HYTTNRPQPQ HHLLRPRRRK RPHSIPTPIL IFRSP.[61]

See also Edit

References Edit

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External links Edit

 
Look up ferritin or apoferritin in Wiktionary, the free dictionary.
  • Ferritins at the U.S. National Library of Medicine Medical Subject Headings (MeSH)
  • Ferritin at Lab Tests Online
  • Overview of all the structural information available in the PDB for UniProt: P02792 (Ferritin light chain) at the PDBe-KB.
  • Overview of all the structural information available in the PDB for UniProt: P02794 (Ferritin heavy chain) at the PDBe-KB.
  • Overview of all the structural information available in the PDB for UniProt: Q8N4E7 (Ferritin, mitochondrial) at the PDBe-KB.

October 14, 2023
ferritin, universal, intracellular, protein, that, stores, iron, releases, controlled, fashion, protein, produced, almost, living, organisms, including, archaea, bacteria, algae, higher, plants, animals, primary, intracellular, iron, storage, protein, both, pr. Ferritin is a universal intracellular protein that stores iron and releases it in a controlled fashion The protein is produced by almost all living organisms including archaea bacteria algae higher plants and animals It is the primary intracellular iron storage protein in both prokaryotes and eukaryotes keeping iron in a soluble and non toxic form In humans it acts as a buffer against iron deficiency and iron overload 3 FerritinStructure of the murine ferritin complex 1 IdentifiersSymbolFerritinPfamPF00210Pfam clanCL0044InterProIPR008331SCOP21fha SCOPe SUPFAMAvailable protein structures Pfam structures ECOD PDBRCSB PDB PDBe PDBjPDBsumstructure summaryferritin light polypeptideIdentifiersSymbolFTLNCBI gene2512HGNC3999OMIM134790RefSeqNM 000146UniProtP02792Other dataLocusChr 19 q13 3 13 4Search forStructuresSwiss modelDomainsInterProferritin heavy polypeptide 1IdentifiersSymbolFTH1Alt symbolsFTHL6NCBI gene2495HGNC3976OMIM134770RefSeqNM 002032UniProtP02794Other dataLocusChr 11 q13Search forStructuresSwiss modelDomainsInterProferritin mitochondrialCrystallographic structure of mitochondrial ferritin 2 IdentifiersSymbolFTMTNCBI gene94033HGNC17345OMIM608847RefSeqNM 177478UniProtQ8N4E7Other dataLocusChr 5 q23 1Search forStructuresSwiss modelDomainsInterProFerritin is found in most tissues as a cytosolic protein but small amounts are secreted into the serum where it functions as an iron carrier Plasma ferritin is also an indirect marker of the total amount of iron stored in the body hence serum ferritin is used as a diagnostic test for iron deficiency anemia 4 Aggregated ferritin transforms into a toxic form of iron called hemosiderin 5 Ferritin is a globular protein complex consisting of 24 protein subunits forming a hollow nanocage with multiple metal protein interactions 6 Ferritin that is not combined with iron is called apoferritin citation needed Contents 1 Gene 2 Protein structure 3 Function 3 1 Iron storage 3 2 Ferroxidase activity 3 3 Immune response 3 4 Stress response 3 5 Mitochondria 3 6 Yolk 4 Tissue distribution 5 Diagnostic uses 5 1 Normal ranges 5 2 Deficiency 5 3 Excess 5 4 In chronic liver diseases 6 Applications 7 Notes 8 See also 9 References 10 External linksGene EditFerritin genes are highly conserved between species All vertebrate ferritin genes have three introns and four exons 7 In human ferritin introns are present between amino acid residues 14 and 15 34 and 35 and 82 and 83 in addition there are one to two hundred untranslated bases at either end of the combined exons 8 The tyrosine residue at amino acid position 27 is thought to be associated with biomineralization 9 Protein structure EditFerritin is a hollow globular protein of mass 474 kDa and comprising 24 subunits Typically it has internal and external diameters of about 8 and 12 nm respectively 10 The nature of these subunits varies by class of organism In vertebrates the subunits are of two types light L and heavy H which have apparent molecular mass of 19 kDa and 21 kDa respectively their sequences are homologous about 50 identical 8 Amphibians have an additional M type of ferritin 11 Plants and bacteria have a single ferritin it most closely resembles the vertebrate H type 11 In the gastropods of the genus Lymnaea two types have been recovered from somatic cells and the yolk respectively see below 11 In the pearl oyster Pinctada fucata an additional subunit resembling Lymnaea soma ferritin is associated with shell formation 12 In the parasite Schistosoma two types are present one in males the other in females 11 All the aforementioned ferritins are similar in terms of their primary sequence with the vertebrate H type 11 In E coli a 20 similarity to human H ferritin is observed 11 Some ferritin complexes in vertebrates are hetero oligomers of two highly related gene products with slightly different physiological properties The ratio of the two homologous proteins in the complex depends on the relative expression levels of the two genes Inside the ferritin shell iron ions form crystallites together with phosphate and hydroxide ions The resulting particle is similar to ferrihydrite Each ferritin complex can store about 4500 iron Fe3 ions 8 11 A human mitochondrial ferritin MtF was found to express as a pro protein 13 When a mitochondrion takes it up it processes it into a mature protein similar to the ferritins found in the cytoplasm which it assembles to form functional ferritin shells Unlike other human ferritins it appears to have no introns in its genetic code An X ray diffraction study has revealed that its diameter is 1 70 angstroms 0 17 nm it contains 182 residues and is 67 helical The mitochondrial ferritin s Ramachandran plot 14 shows its structure to be mainly alpha helical with a low prevalence of beta sheets Function EditIron storage Edit nbsp Iron uptake through the 3 fold channel of ferritinFerritin is present in every cell type 8 It serves to store iron in a non toxic form to deposit it in a safe form and to transport it to areas where it is required 15 The function and structure of the expressed ferritin protein varies in different cell types This is controlled primarily by the amount and stability of messenger RNA mRNA but also by changes in how the mRNA is stored and how efficiently it is transcribed 8 One major trigger for the production of many ferritins is the mere presence of iron 8 an exception is the yolk ferritin of Lymnaea sp which lacks an iron responsive unit 11 Free iron is toxic to cells as it acts as a catalyst in the formation of free radicals from reactive oxygen species via the Fenton reaction 16 Hence vertebrates have an elaborate set of protective mechanisms to bind iron in various tissue compartments discuss Within cells iron is stored in a protein complex as ferritin or the related complex hemosiderin Apoferritin binds to free ferrous iron and stores it in the ferric state As ferritin accumulates within cells of the reticuloendothelial system protein aggregates are formed as hemosiderin Iron in ferritin or hemosiderin can be extracted for release by the RE cells although hemosiderin is less readily available Under steady state conditions the level of ferritin in the blood serum correlates with total body stores of iron thus the serum ferritin FR5Rl is the most convenient laboratory test to estimate iron stores citation needed Because iron is an important mineral in mineralization ferritin is employed in the shells of organisms such as molluscs to control the concentration and distribution of iron thus sculpting shell morphology and colouration 17 18 It also plays a role in the haemolymph of the polyplacophora where it serves to rapidly transport iron to the mineralizing radula 19 Iron is released from ferritin for use by ferritin degradation which is performed mainly by lysosomes 20 Ferroxidase activity Edit Vertebrate ferritin consists of two or three subunits which are named based on their molecular weight L light H heavy and M middle subunits The M subunit has only been reported in bullfrogs In bacteria and archaea ferritin consists of one subunit type 21 H and M subunits of eukaryotic ferritin and all subunits of bacterial and archaeal ferritin are H type and have ferroxidase activity which is the conversion of iron from the ferrous Fe2 to ferric Fe3 forms This limits the deleterious reaction which occurs between ferrous iron and hydrogen peroxide known as the Fenton reaction which produces the highly damaging hydroxyl radical The ferroxidase activity occurs at a diiron binding site in the middle of each H type subunits 21 22 After oxidation of Fe II the Fe III product stays metastably in the ferroxidase center and is displaced by Fe II 22 23 a mechanism that appears to be common among ferritins of all three kingdoms of life 21 The light chain of ferritin has no ferroxidase activity but may be responsible for the electron transfer across the protein cage 24 Immune response Edit Ferritin concentrations increase drastically in the presence of an infection or cancer Endotoxins are an up regulator of the gene coding for ferritin thus causing the concentration of ferritin to rise By contrast organisms such as Pseudomonas although possessing endotoxin cause plasma ferritin levels to drop significantly within the first 48 hours of infection Thus the iron stores of the infected body are denied to the infective agent impeding its metabolism 25 Stress response Edit The concentration of ferritin has been shown to increase in response to stresses such as anoxia 26 which implies that it is an acute phase protein 27 Mitochondria Edit Mitochondrial ferritin has many roles pertaining to molecular function It participates in ferroxidase activity binding iron ion binding oxidoreductase activity ferric iron binding metal ion binding as well as transition metal binding Within the realm of biological processes it participates in oxidation reduction iron ion transport across membranes and cellular iron ion homeostasis citation needed Yolk Edit In some snails the protein component of the egg yolk is primarily ferritin 28 This is a different ferritin with a different genetic sequence from the somatic ferritin It is produced in the midgut glands and secreted into the haemolymph whence it is transported to the eggs 28 Tissue distribution EditIn vertebrates ferritin is usually found within cells although it is also present in smaller quantities in the plasma 25 Diagnostic uses EditSerum ferritin levels are measured in medical laboratories as part of the iron studies workup for iron deficiency anemia 6 They are measured in nanograms per milliliter ng mL or micrograms per liter mg L the two units are essentially equivalent The ferritin levels measured usually have a direct correlation with the total amount of iron stored in the body However ferritin levels may be artificially high in cases of anemia of chronic disease where ferritin is elevated in its capacity as an inflammatory acute phase protein and not as a marker for iron overload citation needed Normal ranges Edit A normal ferritin blood level referred to as the reference interval is determined by many testing laboratories The ranges for ferritin can vary between laboratories but typical ranges would be between 40 and 300 ng mL mg L for males and 20 200 ng mL mg L for females 29 Normal ferritin blood levels according to sex and age citation needed Adult males 40 300 ng mL mg L 29 Adult females 20 200 ng mL mg L 29 Children 6 months to 15 years 50 140 ng mL mg L Infants 1 to 5 months 50 200 ng mL mg L Neonates 25 200 ng mL mg L Deficiency Edit According to a 2014 review in the New England Journal of Medicine stated that a ferritin level below 30 ng mL indicates iron deficiency while a level below 10 ng mL indicates iron deficiency anemia 29 A 2020 World Health Organization guideline states that ferritin indicates iron deficiency below 12 ng mL in apparently healthy children under 5 and 15 ng mL in apparently healthy individuals of 5 and over 30 Some studies suggest that women with fatigue and ferritin below 50 ng mL see reduced fatigue after iron supplementation 31 32 In the setting of anemia low serum ferritin is the most specific lab finding for iron deficiency anemia 33 However it is less sensitive since its levels are increased in the blood by infection or any type of chronic inflammation 34 and these conditions may convert what would otherwise be a low level of ferritin from lack of iron into a value in the normal range For this reason low ferritin levels carry more information than those in the normal range A falsely low blood ferritin equivalent to a false positive test is very uncommon 34 but can result from a hook effect of the measuring tools in extreme cases 35 Low ferritin may also indicate hypothyroidism vitamin C deficiency or celiac disease citation needed Low serum ferritin levels are seen in some patients with restless legs syndrome not necessarily related to anemia but perhaps due to low iron stores short of anemia 36 37 Vegetarianism is not a cause of low serum ferritin levels according to the American Dietetic Association s position in 2009 Incidence of iron deficiency anemia among vegetarians is similar to that of non vegetarians Although vegetarian adults have lower iron stores than non vegetarians their serum ferritin levels are usually within the normal range 38 Excess Edit If ferritin is high there is iron in excess or else there is an acute inflammatory reaction in which ferritin is mobilized without iron excess For example ferritins may be high in infection without signaling body iron overload Ferritin is also used as a marker for iron overload disorders such as hemochromatosis or hemosiderosis Adult onset Still s disease some porphyrias and hemophagocytic lymphohistiocytosis macrophage activation syndrome are diseases in which the ferritin level may be abnormally raised As ferritin is also an acute phase reactant it is often elevated in the course of disease A normal C reactive protein can be used to exclude elevated ferritin caused by acute phase reactions citation needed Ferritin has been shown to be elevated in some cases of COVID 19 and may correlate with worse clinical outcome 39 40 Ferritin and IL 6 are considered to be possible immunological biomarkers for severe and fatal cases of COVID 19 Ferritin and C reactive protein may be possible screening tools for early diagnosis of systemic inflammatory response syndrome in cases of COVID 19 41 42 According to a study of anorexia nervosa patients ferritin can be elevated during periods of acute malnourishment perhaps due to iron going into storage as intravascular volume and thus the number of red blood cells falls 43 Another study suggests that due to the catabolic nature of anorexia nervosa isoferritins may be released Furthermore ferritin has significant non storage roles within the body such as protection from oxidative damage The rise of these isoferritins may contribute to an overall increase in ferritin concentration The measurement of ferritin through immunoassay or immunoturbidimeteric methods may also be picking up these isoferritins thus not a true reflection of iron storage status 44 Studies reveal that a transferrin saturation serum iron concentration total iron binding capacity over 60 percent in men and over 50 percent in women identified the presence of an abnormality in iron metabolism hereditary hemochromatosis heterozygotes and homozygotes with approximately 95 percent accuracy This finding helps in the early diagnosis of hereditary hemochromatosis especially while serum ferritin still remains low The retained iron in hereditary hemochromatosis is primarily deposited in parenchymal cells with reticuloendothelial cell accumulation occurring very late in the disease This is in contrast to transfusional iron overload in which iron deposition occurs first in the reticuloendothelial cells and then in parenchymal cells This explains why ferritin levels remain relative low in hereditary hemochromatosis while transferrin saturation is high 45 46 In chronic liver diseases Edit Hematological abnormalities often associate with chronic liver diseases Both iron overload and iron deficient anemia have been reported in patients with liver cirrhosis 47 48 The former is mainly due to reduced hepcidin level caused by the decreased synthetic capacity of the liver while the latter is due to acute and chronic bleeding caused by portal hypertension Inflammation is also present in patients with advanced chronic liver disease As a consequence elevated hepatic and serum ferritin levels are consistently reported in chronic liver diseases 49 50 51 Studies showed association between high serum ferritin levels and increased risk of short term mortality in cirrhotic patients with acute decompensation 52 and acute on chronic liver failure 53 An other study found association between high serum ferritin levels and increased risk of long term mortality in compensated and stable decompensated cirrhotic patients 54 The same study demonstrated that increased serum ferritin levels could predict the development of bacterial infection in stable decompensated cirrhotic patients while in compensated cirrhotic patients the appearance of the very first acute decompensation episode showed higher incidence in patients with low serum ferritin levels This latter finding was explaind by the association between chronic bleeding and increased portal pressure 54 Applications EditFerritin is used in materials science as a precursor in making iron nanoparticles for carbon nanotube growth by chemical vapor deposition Cavities formed by ferritin and mini ferritins Dps proteins have been successfully used as the reaction chamber for the fabrication of metal nanoparticles NPs 55 56 57 58 Protein shells served as a template to restrain particle growth and as a coating to prevent coagulation aggregation between NPs Using various sizes of protein shells various sizes of NPs can be easily synthesized for chemical physical and bio medical applications 6 59 Experimental COVID 19 vaccines have been produced that display the spike protein s receptor binding domain on the surface of ferritin nanoparticles 60 Notes EditThe primary sequence of human ferritin is MTTASTSQVR QNYHQDSEAA INRQINLELY ASYVYLSMSY YFDRDDVALK NFAKYFLHQS HEEREHAEKL MKLQNQRGGR IFLQDIKKPD CDDWESGLNA MECALHLEKN VNQSLLEFPS PISPSPSCWH HYTTNRPQPQ HHLLRPRRRK RPHSIPTPIL IFRSP 61 See also EditBacterioferritin DNA binding protein from starved cells Ferritin light chain TransferrinReferences Edit PDB 1lb3 Granier T Langlois d Estaintot B Gallois B Chevalier JM Precigoux G Santambrogio P Arosio P January 2003 Structural description of the active sites of mouse L chain ferritin at 1 2 A resolution Journal of Biological Inorganic Chemistry 8 1 2 105 11 doi 10 1007 s00775 002 0389 4 PMID 12459904 S2CID 20756710 PDB 1r03 Langlois d Estaintot B Santambrogio P Granier T Gallois B Chevalier JM Precigoux G Levi S Arosio P July 2004 Crystal structure and biochemical properties of the human mitochondrial ferritin and its mutant Ser144Ala Journal of Molecular Biology 340 2 277 93 doi 10 1016 j jmb 2004 04 036 PMID 15201052 Casiday R Frey R Iron Use and Storage in the Body Ferritin and Molecular Representations Department of Chemistry Washington University in St Louis Wang W Knovich MA Coffman LG Torti FM Torti SV August 2010 Serum ferritin Past present and future Biochimica et Biophysica Acta BBA General Subjects 1800 8 760 9 doi 10 1016 j bbagen 2010 03 011 PMC 2893236 PMID 20304033 MacKenzie EL Iwasaki K Tsuji Y June 2008 Intracellular iron transport and storage from molecular mechanisms to health implications Antioxidants amp Redox Signaling 10 6 997 1030 doi 10 1089 ars 2007 1893 PMC 2932529 PMID 18327971 a b c Theil EC 2012 Ferritin protein nanocages the story Nanotechnology Perceptions 8 1 7 16 doi 10 4024 N03TH12A ntp 08 01 PMC 3816979 PMID 24198751 Torti FM Torti SV May 2002 Regulation of ferritin genes and protein Blood 99 10 3505 16 doi 10 1182 blood V99 10 3505 PMID 11986201 a b c d e f Theil EC 1987 Ferritin structure gene regulation and cellular function in animals plants and microorganisms Annual Review of Biochemistry 56 1 289 315 doi 10 1146 annurev bi 56 070187 001445 PMID 3304136 De Zoysa M Lee J September 2007 Two ferritin subunits from disk abalone Haliotis discus discus cloning characterization and expression analysis Fish amp Shellfish Immunology 23 3 624 35 doi 10 1016 j fsi 2007 01 013 PMID 17442591 Ferritin Structure and Its Biomedical Implications Metallic BioNano Particles Universidad de Granada Archived from the original on 2016 08 27 Retrieved 2016 01 16 a b c d e f g h Andrews SC Arosio P Bottke W Briat JF von Darl M Harrison PM Laulhere JP Levi S Lobreaux S Yewdall SJ 1992 Structure function and evolution of ferritins Journal of Inorganic Biochemistry 47 3 4 161 74 doi 10 1016 0162 0134 92 84062 R PMID 1431878 Zhang Y Meng Q Jiang T Wang H Xie L Zhang R May 2003 A novel ferritin subunit involved in shell formation from the pearl oyster Pinctada fucata Comparative Biochemistry and Physiology Part B Biochemistry amp Molecular Biology 135 1 43 54 doi 10 1016 S1096 4959 03 00050 2 PMID 12781972 Levi S Corsi B Bosisio M Invernizzi R Volz A Sanford D Arosio P Drysdale J July 2001 A human mitochondrial ferritin encoded by an intronless gene The Journal of Biological Chemistry 276 27 24437 40 doi 10 1074 jbc C100141200 PMID 11323407 Lovell SC Davis IW Arendall WB de Bakker PI Word JM Prisant MG Richardson JS Richardson DC February 2003 Structure validation by Calpha geometry phi psi and Cbeta deviation PDF Proteins 50 3 437 50 doi 10 1002 prot 10286 PMID 12557186 S2CID 8358424 Archived from the original PDF on 12 October 2012 MolProbity Ramachandran analysis Seckback J 1982 Ferreting out the secrets of plant ferritin A review Journal of Plant Nutrition 5 4 7 369 394 doi 10 1080 01904168209362966 Orino K Lehman L Tsuji Y Ayaki H Torti SV Torti FM July 2001 Ferritin and the response to oxidative stress The Biochemical Journal 357 Pt 1 241 7 doi 10 1042 0264 6021 3570241 PMC 1221947 PMID 11415455 Jackson DJ Worheide G Degnan BM 2007 Dynamic expression of ancient and novel molluscan shell genes during ecological transitions BMC Evolutionary Biology 7 160 doi 10 1186 1471 2148 7 160 PMC 2034539 PMID 17845714 Yano M Nagai K Morimoto K Miyamoto H June 2006 Shematrin a family of glycine rich structural proteins in the shell of the pearl oyster Pinctada fucata Comparative Biochemistry and Physiology Part B Biochemistry amp Molecular Biology 144 2 254 62 doi 10 1016 j cbpb 2006 03 004 PMID 16626988 Kyung Suk K Webb J Macey D 1986 Properties and role of ferritin in the hemolymph of the chiton Clavarizona hirtosa Biochimica et Biophysica Acta BBA General Subjects 884 3 387 394 doi 10 1016 0304 4165 86 90188 1 Zhang Y Mikhael M Xu D Li Y Soe Lin S Ning B et al October 2010 Lysosomal proteolysis is the primary degradation pathway for cytosolic ferritin and cytosolic ferritin degradation is necessary for iron exit Antioxidants amp Redox Signaling 13 7 999 1009 doi 10 1089 ars 2010 3129 PMID 20406137 a b c Honarmand Ebrahimi K Hagedoorn PL Hagen WR January 2015 Unity in the biochemistry of the iron storage proteins ferritin and bacterioferritin Chemical Reviews 115 1 295 326 doi 10 1021 cr5004908 PMID 25418839 a b Honarmand Ebrahimi K Bill E Hagedoorn PL Hagen WR November 2012 The catalytic center of ferritin regulates iron storage via Fe II Fe III displacement Nature Chemical Biology 8 11 941 8 doi 10 1038 nchembio 1071 PMID 23001032 Watt RK March 2013 A unified model for ferritin iron loading by the catalytic center implications for controlling free iron during oxidative stress ChemBioChem 14 4 415 9 doi 10 1002 cbic 201200783 PMID 23404831 S2CID 41485685 Carmona U Li L Zhang L Knez M December 2014 Ferritin light chain subunits key elements for the electron transfer across the protein cage Chemical Communications 50 97 15358 61 doi 10 1039 c4cc07996e PMID 25348725 a b Ong DS Wang L Zhu Y Ho B Ding JL 2005 The response of ferritin to LPS and acute phase of Pseudomonas infection Journal of Endotoxin Research 11 5 267 80 doi 10 1179 096805105X58698 PMID 16262999 Larade K Storey KB March 2004 Accumulation and translation of ferritin heavy chain transcripts following anoxia exposure in a marine invertebrate The Journal of Experimental Biology 207 Pt 8 1353 60 doi 10 1242 jeb 00872 PMID 15010486 Beck G Ellis TW Habicht GS Schluter SF Marchalonis JJ January 2002 Evolution of the acute phase response iron release by echinoderm Asterias forbesi coelomocytes and cloning of an echinoderm ferritin molecule Developmental and Comparative Immunology 26 1 11 26 doi 10 1016 S0145 305X 01 00051 9 PMID 11687259 a b Bottke W Burschyk M Volmer J 1988 On the origin of the yolk protein ferritin in snails Roux s Archives of Developmental Biology 197 7 377 382 doi 10 1007 BF00398988 PMID 28305744 S2CID 34033340 a b c d Camaschella Clara 2015 05 07 Longo Dan L ed Iron Deficiency Anemia New England Journal of Medicine 372 19 1832 1843 doi 10 1056 NEJMra1401038 ISSN 0028 4793 PMID 25946282 S2CID 17628280 World Health Organization 2020 WHO guideline on use of ferritin concentrations to assess iron status in individuals and populations Geneva Switzerland ISBN 978 92 4 000012 4 OCLC 1265083396 a href Template Cite book html title Template Cite book cite book a CS1 maint location missing publisher link Verdon F Burnand B Stubi CL Bonard C Graff M Michaud A Bischoff T de Vevey M Studer JP Herzig L Chapuis C Tissot J Pecoud A Favrat B May 2003 Iron supplementation for unexplained fatigue in non anaemic women double blind randomised placebo controlled trial BMJ Clinical Research Ed 326 7399 1124 0 doi 10 1136 bmj 326 7399 1124 PMC 156009 PMID 12763985 Vaucher P Druais PL Waldvogel S Favrat B August 2012 Effect of iron supplementation on fatigue in nonanemic menstruating 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2021 Biomarkers of cytokine storm as red flags for severe and fatal COVID 19 cases A living systematic review and meta analysis PLOS ONE 16 6 e0253894 Bibcode 2021PLoSO 1653894M doi 10 1371 journal pone 0253894 PMC 8241122 PMID 34185801 Dance A 10 April 2020 What is a cytokine storm Knowable Magazine Annual Reviews Retrieved 9 August 2021 Kennedy A Kohn M Lammi A Clarke S August 2004 Iron status and haematological changes in adolescent female inpatients with anorexia nervosa Journal of Paediatrics and Child Health 40 8 430 2 doi 10 1111 j 1440 1754 2004 00432 x PMID 15265182 S2CID 26269832 Tran J Story C Moore D Metz M September 2013 Unexpected increased ferritin concentration in patients with anorexia nervosa Annals of Clinical Biochemistry 50 Pt 5 504 6 doi 10 1177 0004563213490289 PMID 23897102 S2CID 9927714 Bacon BR Adams PC Kowdley KV Powell LW Tavill AS July 2011 Diagnosis and management of hemochromatosis 2011 practice guideline by the American Association for the Study of Liver 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Gastroenterology 21 1 94 doi 10 1186 s12876 021 01669 w PMC 7923668 PMID 33653274 Kasyutich O Ilari A Fiorillo A Tatchev D Hoell A Ceci P March 2010 Silver Ion Incorporation and Nanoparticle Formation inside the Cavity ofPyrococcus furiosusFerritin Structural and Size Distribution Analyses Journal of the American Chemical Society 132 10 3621 7 doi 10 1021 ja910918b PMID 20170158 Uchida M Flenniken ML Allen M Willits DA Crowley BE Brumfield S Willis AF Jackiw L Jutila M Young MJ Douglas T December 2006 Targeting of Cancer Cells with Ferrimagnetic Ferritin Cage Nanoparticles Journal of the American Chemical Society 128 51 16626 33 doi 10 1021 ja0655690 PMID 17177411 Li M Viravaidya C Mann S September 2007 Polymer Mediated Synthesis of Ferritin Encapsulated Inorganic Nanoparticles Small 3 9 1477 81 doi 10 1002 smll 200700199 PMID 17768776 Ueno T Suzuki M Goto T Matsumoto T Nagayama K Watanabe Y May 2004 Size Selective Olefin Hydrogenation by a Pd Nanocluster Provided in an Apo Ferritin Cage Angewandte Chemie 43 19 2527 30 doi 10 1002 anie 200353436 PMID 15127443 Stanford s Single Dose Nanoparticle Vaccine for COVID 19 On SciTechDaily January 10 2021 Source Stanford University Wang W Huang B Zhu Y Tan W Zhu M March 2021 Ferritin nanoparticle based SARS CoV 2 RBD vaccine induces a persistent antibody response and long term memory in mice Cellular amp Molecular Immunology 18 3 749 751 doi 10 1038 s41423 021 00643 6 PMC 7880661 PMID 33580169 Ferritin Homo sapiens Human External links Edit nbsp Look up ferritin or apoferritin in Wiktionary the free dictionary Ferritins at the U S National Library of Medicine Medical Subject Headings MeSH Ferritin at Lab Tests Online Overview of all the structural information available in the PDB for UniProt P02792 Ferritin light chain at the PDBe KB Overview of all the structural information available in the PDB for UniProt P02794 Ferritin heavy chain at the PDBe KB Overview of all the structural information available in the PDB for UniProt Q8N4E7 Ferritin mitochondrial at the PDBe KB Retrieved from https en wikipedia org w index php title Ferritin amp oldid 1178065894, wikipedia, wiki, book, books, library,

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