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Wikipedia

Biotin

January 01, 1970

Biotin (also known as vitamin B7 or vitamin H) is one of the B vitamins.[1][2][3] It is involved in a wide range of metabolic processes, both in humans and in other organisms, primarily related to the utilization of fats, carbohydrates, and amino acids.[4] The name biotin, borrowed from the German Biotin, derives from the Ancient Greek word βίοτος (bíotos; 'life') and the suffix "-in" (a suffix used in chemistry usually to indicate 'forming').[5] Biotin appears as a white, needle-like crystalline solid.[6]

Biotin
Names
Preferred IUPAC name
5-[(3aS,4S,6aR)-2-Oxohexahydro-1H-thieno[3,4-d]imidazol-4-yl]pentanoic acid
Other names
Vitamin B7
Identifiers
  • 58-85-5 Y
3D model (JSmol)
  • Interactive image
  • Interactive image
ChEBI
  • CHEBI:15956 Y
ChEMBL
  • ChEMBL857 Y
ChemSpider
  • 149962 Y
DrugBank
  • DB00121 Y
ECHA InfoCard 100.000.363
  • 4787
KEGG
  • D00029 Y
  • 171548
UNII
  • 6SO6U10H04 Y
  • DTXSID7022679
  • InChI=1S/C10H16N2O3S/c13-8(14)4-2-1-3-7-9-6(5-16-7)11-10(15)12-9/h6-7,9H,1-5H2,(H,13,14)(H2,11,12,15)/t6-,7-,9-/m0/s1 Y
    Key: YBJHBAHKTGYVGT-ZKWXMUAHSA-N Y
  • InChI=1/C10H16N2O3S/c13-8(14)4-2-1-3-7-9-6(5-16-7)11-10(15)12-9/h6-7,9H,1-5H2,(H,13,14)(H2,11,12,15)/t6-,7-,9-/m0/s1
    Key: YBJHBAHKTGYVGT-ZKWXMUAHBB
  • O=C1N[C@@H]2[C@@H](SC[C@@H]2N1)CCCCC(=O)O
  • C1[C@H]2[C@@H]([C@@H](S1)CCCCC(=O)O)NC(=O)N2
Properties
C10H16N2O3S
Molar mass 244.31 g·mol−1
Appearance White crystalline needles
Melting point 232 to 233 °C (450 to 451 °F; 505 to 506 K)
22 mg/100 mL
Pharmacology
A11HA05 (WHO)
Hazards
NFPA 704 (fire diamond)
Health 1: Exposure would cause irritation but only minor residual injury. E.g. turpentineFlammability 1: Must be pre-heated before ignition can occur. Flash point over 93 °C (200 °F). E.g. canola oilInstability 0: Normally stable, even under fire exposure conditions, and is not reactive with water. E.g. liquid nitrogenSpecial hazards (white): no code
1
1
0
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
Y verify (what is YN ?)

Chemical description edit

Biotin is classified as a heterocyclic compound, with a sulfur-containing tetrahydrothiophene ring fused to a ureido group. A C5-carboxylic acid side chain is appended to the former ring. The ureido ring, containing the −N−CO−N− group, serves as the carbon dioxide carrier in carboxylation reactions.[7] Biotin is a coenzyme for five carboxylase enzymes, which are involved in the catabolism of amino acids and fatty acids, synthesis of fatty acids, and gluconeogenesis.[3][4] Biotinylation of histone proteins in nuclear chromatin plays a role in chromatin stability and gene expression.[4][8]

Dietary recommendations edit

The US National Academy of Medicine updated Dietary Reference Intakes for many vitamins in 1998. At that time there was insufficient information to establish estimated average requirement or recommended dietary allowance, terms that exist for most vitamins. In instances such as this, the academy sets adequate intakes (AIs) with the understanding that at some later date, when the physiological effects of biotin are better understood, AIs will be replaced by more exact information. The biotin AIs for both males and females are: 5 μg/day of biotin for 0-to-6-month-olds, 6 μg/day of biotin for 7-to-12-month-olds, 8 μg/day of biotin for 1-to-3-year-olds, 12 μg/day of biotin for 4-to-8-year-olds, 20 μg/day of biotin for 9-to-13-year-olds, 25 μg/day of biotin for 14-to-18-year-olds, and 30 μg/day of biotin for those 19 years old and older. The biotin AIs for females who are either pregnant or lactating, respectively, are: 30 μg/day of biotin for pregnant females 14-to-50-years old and 35 μg/day of biotin for lactating females 14-to-50-years old.[2] Australia and New Zealand set AIs similar to the US.[9]

The European Food Safety Authority (EFSA) also identifies AIs, setting values at 40 μg/day for adults, pregnancy at 40 μg/day, and breastfeeding at 45 μg/day. For children ages 1–17 years, the AIs increase with age from 20 to 35 μg/day.[10]

Safety edit

The US National Academy of Medicine estimates upper limits for vitamins and minerals when evidence for a true limit is sufficient. For biotin, however, there is no upper limit because adverse effects of high biotin intake have not been determined.[2] The EFSA also reviewed safety and reached the same conclusion as in the United States.[11]

Labeling regulations edit

For US food and dietary supplement labeling purposes the amount in a serving is expressed as a percent of daily value. For biotin labeling purposes 100% of the daily value was 300 μg/day, but as of May 27, 2016, it was revised to 30 μg/day to bring it into an agreement with the adequate intake.[12][13] Compliance with the updated labeling regulations was required by January 1, 2020, for manufacturers with US$10 million or more in annual food sales, and by January 1, 2021, for manufacturers with lower volume food sales.[14][15] A table of the old and new adult daily values is provided at Reference Daily Intake.

Sources edit

Source[16] Amount
(μg / 100 g)
Chicken liver 187
Beef liver 42
Eggs 21
Egg white 5.8
Egg yolk 27
Salmon, canned in water 5.9
Pork chop 4.5
Turkey breast 0.7
Tuna, white, canned 0.7
Source[16] Amount
(μg / 100 g)
Peanuts, roasted 17.5
Sunflower seeds, roasted 7.8
Almonds, roasted 4.4
Sweet potato 1.5
Broccoli 0.9
Tomato 0.7
Strawberry 1.5
Avocado 1.0
Corn, canned 0.05
Source[16] Amount
(μg / 100 g)
Cheese 1.4
Milk 0.1
Oatmeal 0.1
Bread 0.1
French fries 0.3
Wine 0.1
Beer 0.1
Potatoes, mashed 0.1

Biotin is stable at room temperature and is not destroyed by cooking. The dietary biotin intake in Western populations has been estimated to be in the range of 35 to 70 μg/day. Nursing infants ingest about 6 μg/day.[4] Biotin is available in dietary supplements, individually or as an ingredient in multivitamins.[1][3]

According to the Global Fortification Data Exchange, biotin deficiency is so rare that no countries require that foods be fortified.[17]

Physiology edit

Biotin is a water-soluble B vitamin. Consumption of large amounts as a dietary supplement results in absorption, followed by excretion into urine as biotin. Consumption of biotin as part of a normal diet results in urinary excretion of biotin and biotin metabolites.[4]

Absorption edit

Biotin in food is bound to proteins. Digestive enzymes reduce the proteins to biotin-bound peptides. The intestinal enzyme biotinidase, found in pancreatic secretions and in the brush border membranes of all three parts of the small intestine, frees biotin, which is then absorbed from the small intestine.[4] When consumed as a biotin dietary supplement, absorption is nonsaturable, meaning that even very high amounts are absorbed effectively. Transport across the jejunum is faster than across the ileum.[4]

The large intestine microbiota synthesize amounts of biotin estimated to be similar to the amount taken in the diet, and a significant portion of this biotin exists in the free (protein-unbound) form and, thus, is available for absorption. How much is absorbed in humans is unknown, although a review did report that human epithelial cells of the colon in vitro demonstrated an ability to uptake biotin.[18]

Once absorbed, sodium-dependent multivitamin transporter (SMVT) mediates biotin uptake into the liver.[4] SMVT also binds pantothenic acid, so high intakes of either of these vitamins can interfere with transport of the other.[19]

Metabolism and excretion edit

Biotin catabolism occurs via two pathways. In one, the valeric acid sidechain is cleaved, resulting in bisnorbiotin. In the other pathway, the sulfur is oxidized, resulting in biotin sulfoxide. Urine content is proportionally about half biotin, plus bisnorbiotin, biotin sulfoxide, and small amounts of other metabolites.[4]

Factors that affect biotin requirements edit

Chronic alcohol use is associated with a significant reduction in plasma biotin.[20] Intestinal biotin uptake also appears to be sensitive to the effect of the anti-epilepsy drugs carbamazepine and primidone.[20] Relatively low levels of biotin have also been reported in the urine or plasma of patients who have had a partial gastrectomy or have other causes of achlorhydria, as well as burn patients, elderly individuals, and athletes.[21] Pregnancy and lactation may be associated with an increased demand for biotin. In pregnancy, this may be due to a possible acceleration of biotin catabolism, whereas, in lactation, the higher demand has yet to be elucidated. Recent studies have shown marginal biotin deficiency can be present in human gestation, as evidenced by increased urinary excretion of 3-hydroxyisovaleric acid, decreased urinary excretion of biotin and bisnorbiotin, and decreased plasma concentration of biotin.[4]

Biosynthesis edit

Biotin, synthesized in plants, is essential to plant growth and development.[22] Bacteria also synthesize biotin,[23] and it is thought that bacteria resident in the large intestine may synthesize biotin that is absorbed and utilized by the host organism.[18]

Biosynthesis starts from two precursors, alanine and pimeloyl-CoA. These form 7-keto-8-aminopelargonic acid (KAPA). KAPA is transported from plant peroxisomes to mitochondria where it is converted to 7,8-diaminopelargonic acid (DAPA) with the help of the enzyme, BioA. The enzyme dethiobiotin synthetase catalyzes the formation of the ureido ring via a DAPA carbamate activated with ATP, creating dethiobiotin with the help of the enzyme, BioD, which is then converted into biotin which is catalyzed by BioB.[24] The last step is catalyzed by biotin synthase, a radical SAM enzyme. The sulfur is donated by an unusual [2Fe-2S] ferredoxin.[25] Depending on the species of bacteria, Biotin can be synthesized via multiple pathways.[24]

Cofactor biochemistry edit

The enzyme holocarboxylase synthetase covalently attaches biotin to five human carboxylase enzymes:[4]

For the first two, biotin serves as a cofactor responsible for transfer of bicarbonate to acetyl-CoA, converting it to malonyl-CoA for fatty acid synthesis. PC participates in gluconeogenesis. MCC catalyzes a step in leucine metabolism. PCC catalyzes a step in the metabolism of propionyl-CoA.[1][3][4] Metabolic degradation of the biotinylated carboxylases leads to the formation of biocytin. This compound is further degraded by biotinidase to release biotin, which is then reutilized by holocarboxylase synthetase.[4]

Biotinylation of histone proteins in nuclear chromatin is a posttranslational modification that plays a role in chromatin stability and gene expression.[4][8]

Deficiency edit

Main article: Biotin deficiency

Primary biotin deficiency, meaning deficiency as a consequence of too little biotin in the diet, is rare, because biotin is contained in so many foods. Subclinical deficiency can cause mild symptoms, such as hair thinning, brittle fingernails, or skin rash, typically on the face.[2][4]

Aside from inadequate dietary intake (rare), deficiency of biotin can be caused by a genetic disorder that affects biotin metabolism. The most common among these is biotinidase deficiency. Low activity of this enzyme causes a failure to recycle biotin from biocytin. Rarer are carboxylase and biotin transporter deficiences.[4][26] Neonatal screening for biotinidase deficiency started in the United States in 1984, with many countries now also testing for this genetic disorder at birth. Treatment is lifelong dietary supplement with biotin.[1] If biotinidase deficiency goes untreated, it can be fatal.[27]

Diagnosis edit

Low serum and urine biotin are not sensitive indicators of inadequate biotin intake.[4] However, serum testing can be useful for confirmation of consumption of biotin-containing dietary supplements, and whether a period of refraining from supplement use is long enough to eliminate the potential for interfering with drug tests.[28][29] Indirect measures depend on the biotin requirement for carboxylases. 3-Methylcrotonyl-CoA is an intermediate step in the catabolism of the amino acid leucine. In the absence of biotin, the pathway diverts to 3-hydroxyisovaleric acid. Urinary excretion of this compound is an early and sensitive indicator of biotin deficiency.[2][4]

Deficiency as a result of metabolic disorders edit

Biotinidase deficiency is a deficiency of the enzyme that recycles biotin, the consequence of an inherited genetic mutation.[1] Biotinidase catalyzes the cleavage of biotin from biocytin and biotinyl-peptides (the proteolytic degradation products of each holocarboxylase) and thereby recycles biotin.[2] It is also important in freeing biotin from dietary protein-bound biotin.[30] Neonatal screening for biotinidase deficiency started in the United States in 1984,[31] which as of 2017 was reported as required in more than 30 countries.[32]

Profound biotinidase deficiency, defined as less than 10% of normal serum enzyme activity, which has been reported as 7.1 nmol/min/mL, has an incidence of 1 in 40,000 to 1 in 60,000, but with rates as high as 1 in 10,000 in countries with high incidence of consanguineous marriages (second cousin or closer). Partial biotinidase deficiency is defined as 10% to 30% of normal serum activity.[31] Incidence data stems from government mandated newborn screening.[32] For profound deficiency, treatment is oral dosing with 5 to 20 mg per day. Seizures are reported as resolving in hours to days, with other symptoms resolving within weeks.[31] Treatment of partial biotinidase deficiency is also recommended even though some untreated people never manifest symptoms.[31] Lifelong treatment with supplemental biotin is recommended for both profound and partial biotinidase deficiency.[1]

Inherited metabolic disorders characterized by deficient activities of biotin-dependent carboxylases are termed multiple carboxylase deficiency. These include deficiencies in the enzymes holocarboxylase synthetase.[1] Holocarboxylase synthetase deficiency prevents the body's cells from using biotin effectively and thus interferes with multiple carboxylase reactions.[30] There can also be a genetic defect affecting the sodium-dependent multivitamin transporter protein.[26]

Biochemical and clinical manifestations of any of these metabolic disorders can include ketolactic acidosis, organic aciduria, hyperammonemia, rash, hypotonia, seizures, developmental delay, alopecia and coma.[4]

Use in biotechnology edit

Chemically modified versions of biotin are widely used throughout the biotechnology industry to isolate proteins and non-protein compounds for biochemical assays.[33] Because egg-derived avidin binds strongly to biotin with a dissociation constant Kd ≈ 10−15 M,[34] biotinylated compounds of interest can be isolated from a sample by exploiting this highly stable interaction. First, the chemically modified biotin reagents are bound to the targeted compounds in a solution via a process called biotinylation. The choice of which chemical modification to use is responsible for the biotin reagent binding to a specific protein.[33] Second, the sample is incubated with avidin bound to beads, then rinsed, removing all unbound proteins, while leaving only the biotinylated protein bound to avidin. Last, the biotinylated protein can be eluted from the beads with excess free biotin.[35] The process can also utilize bacteria-derived streptavidin bound to beads, but because it has a higher dissociation constant than avidin, very harsh conditions are needed to elute the biotinylated protein from the beads, which often will denature the protein of interest.[34]

Interference with medical laboratory results edit

When people are ingesting high levels of biotin in dietary supplements, a consequence can be clinically significant interference with diagnostic blood tests that use biotin-streptavidin technology. This methodology is commonly used to measure levels of hormones such as thyroid hormones, and other analytes such as 25-hydroxyvitamin D. Biotin interference can produce both falsely normal and falsely abnormal results.[1][36] In the US, biotin as a non-prescription dietary supplement is sold in amounts of 1 to 10 mg per serving, with claims for supporting hair and nail health, and as 300 mg per day as a possibly effective treatment for multiple sclerosis[37][38] (see § Research). Overconsumption of 5 mg/day or higher causes elevated concentration in plasma that interferes with biotin-streptavidin immunoassays in an unpredictable manner.[28][29] Healthcare professionals are advised to instruct patients to stop taking biotin supplements for 48 h or even up to weeks before the test, depending on the specific test, dose, and frequency of biotin uptake.[28] Guidance for laboratory staff is proposed to detect and manage biotin interference.[29]

History edit

Further information: Vitamin § History

In 1916, W. G. Bateman observed that a diet high in raw egg whites caused toxic symptoms in dogs, cats, rabbits, and humans.[39] By 1927, scientists such as Margarete Boas and Helen Parsons had performed experiments demonstrating the symptoms associated with "egg-white injury." They had found that rats fed large amounts of egg-white as their only protein source exhibited neurological dysfunction, hair loss, dermatitis, and eventually, death.[40][41]

In 1936, Fritz Kögl and Benno Tönnis documented isolating a yeast growth factor in a journal article titled "Darstellung von krystallisiertem biotin aus eigelb." (Representation of crystallized biotin from egg yolk).[42] The name biotin derives from the Greek word bios ('to live') and the suffix "-in" (a general chemical suffix used in organic chemistry).[5] Other research groups, working independently, had isolated the same compound under different names. Hungarian scientist Paul Gyorgy began investigating the factor responsible for egg-white injury in 1933 and in 1939, was successful identifying what he called "Vitamin H" (the H represents Haar und Haut, German for 'hair and skin').[43][44] Further chemical characterization of vitamin H revealed that it was water-soluble and present in high amounts in the liver.[45] After experiments performed with yeast and Rhizobium trifolii, West and Wilson isolated a compound they called co-enzyme R.[46][47] By 1940, it was recognized that all three compounds were identical and were collectively given the name: biotin.[48] Gyorgy continued his work on biotin and in 1941 published a paper demonstrating that egg-white injury was caused by the binding of biotin by avidin.[49][50] Unlike for many vitamins, there is insufficient information to establish a recommended dietary allowance, so dietary guidelines identify an "adequate intake" based on best available science with the understanding that at some later date this will be replaced by more exact information.[2][9][10]

Using E. coli, a biosynthesis pathway was proposed by Rolfe and Eisenberg in 1968. The initial step was described as a condensation of pimelyl-CoA and alanine to form 7-oxo-8-aminopelargonic acid. From there, they described three-step process, the last being introducing a sulfur atom to form the tetrahydrothiophene ring.[51]

Research edit

Multiple sclerosis edit

High-dose biotin (300 mg/day = 10,000 times adequate intake) has been used in clinical trials for treatment of multiple sclerosis, a demyelinating autoimmune disease.[37][38] The hypothesis is that biotin may promote remyelination of the myelin sheath of nerve cells, slowing or even reversing neurodegeneration. The proposed mechanisms are that biotin activates acetyl-coA carboxylase, which is a key rate-limiting enzyme during the synthesis of myelin, and by reducing axonal hypoxia through enhanced energy production.[37][38] Clinical trial results are mixed; a 2019 review concluded that a further investigation of the association between multiple sclerosis symptoms and biotin should be undertaken,[37] whereas two 2020 reviews of a larger number of clinical trials reported no consistent evidence for benefits,[52] and some evidence for increased disease activity and higher risk of relapse.[53]

Hair, nails, skin edit

In the United States, biotin is promoted as a dietary supplement for strengthening hair and fingernails, though scientific data supporting these outcomes in humans are very weak.[3][54][55] A review of the fingernails literature reported brittle nail improvement as evidence from two pre-1990 clinical trials that had administered an oral dietary supplement of 2.5 mg/day for several months, without a placebo control comparison group. There is no more recent clinical trial literature.[54] A review of biotin as treatment for hair loss identified case studies of infants and young children with genetic defect biotin deficiency having improved hair growth after supplementation, but went on to report that "there have been no randomized, controlled trials to prove efficacy of supplementation with biotin in normal, healthy individuals."[55] Biotin is also incorporated into topical hair and skin products with similar claims.[56]

The Dietary Supplement Health and Education Act of 1994 states that the US Food and Drug Administration must allow on the product label what are described as "Structure:Function" (S:F) health claims that ingredient(s) are essential for health. For example: Biotin helps maintain healthy skin, hair and nails. If a S:F claim is made, the label must include the disclaimer "This statement has not been evaluated by the Food and Drug Administration. This product is not intended to diagnose, treat, cure, or prevent any disease."[57]

Animals edit

In cattle, biotin is necessary for hoof health. Lameness due to hoof problems is common, with herd prevalence estimated at 10 to 35%.[citation needed] Consequences of lameness include less food consumption, lower milk production, and increased veterinary treatment costs. Results after 4–6 months from supplementing biotin at 20 mg/day into daily diet reduces the risk of lameness.[58][59] A review of controlled trials reported that supplementation at 20 mg/day increased milk yield by 4.8%. The discussion speculated that this could be an indirect consequence of improved hoof health or a direct effect on milk production.[60]

For horses, conditions such as chronic laminitis, cracked hooves, or dry, brittle feet incapable of holding shoes are a common problem. Biotin is a popular nutritional supplement. There are recommendations that horses need 15 to 25 mg/day. Studies report biotin improves the growth of new hoof horn rather than improving the status of existing hoof, so months of supplementation are needed for the hoof wall to be completely replaced.[61]

See also edit

References edit

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External links edit

  •   Media related to Biotin at Wikimedia Commons

January 01, 1970
biotin, also, known, vitamin, vitamin, vitamins, involved, wide, range, metabolic, processes, both, humans, other, organisms, primarily, related, utilization, fats, carbohydrates, amino, acids, name, biotin, borrowed, from, german, derives, from, ancient, gree. Biotin also known as vitamin B7 or vitamin H is one of the B vitamins 1 2 3 It is involved in a wide range of metabolic processes both in humans and in other organisms primarily related to the utilization of fats carbohydrates and amino acids 4 The name biotin borrowed from the German Biotin derives from the Ancient Greek word biotos biotos life and the suffix in a suffix used in chemistry usually to indicate forming 5 Biotin appears as a white needle like crystalline solid 6 Biotin Names Preferred IUPAC name 5 3aS 4S 6aR 2 Oxohexahydro 1H thieno 3 4 d imidazol 4 yl pentanoic acid Other names Vitamin B7 Identifiers CAS Number 58 85 5 Y 3D model JSmol Interactive imageInteractive image ChEBI CHEBI 15956 Y ChEMBL ChEMBL857 Y ChemSpider 149962 Y DrugBank DB00121 Y ECHA InfoCard 100 000 363 IUPHAR BPS 4787 KEGG D00029 Y PubChem CID 171548 UNII 6SO6U10H04 Y CompTox Dashboard EPA DTXSID7022679 InChI InChI 1S C10H16N2O3S c13 8 14 4 2 1 3 7 9 6 5 16 7 11 10 15 12 9 h6 7 9H 1 5H2 H 13 14 H2 11 12 15 t6 7 9 m0 s1 YKey YBJHBAHKTGYVGT ZKWXMUAHSA N YInChI 1 C10H16N2O3S c13 8 14 4 2 1 3 7 9 6 5 16 7 11 10 15 12 9 h6 7 9H 1 5H2 H 13 14 H2 11 12 15 t6 7 9 m0 s1Key YBJHBAHKTGYVGT ZKWXMUAHBB SMILES O C1N C H 2 C H SC C H 2N1 CCCCC O OC1 C H 2 C H C H S1 CCCCC O O NC O N2 Properties Chemical formula C 10H 16N 2O 3S Molar mass 244 31 g mol 1 Appearance White crystalline needles Melting point 232 to 233 C 450 to 451 F 505 to 506 K Solubility in water 22 mg 100 mL Pharmacology ATC code A11HA05 WHO Hazards NFPA 704 fire diamond 110 Except where otherwise noted data are given for materials in their standard state at 25 C 77 F 100 kPa Y verify what is Y N Infobox references Contents 1 Chemical description 2 Dietary recommendations 2 1 Safety 2 2 Labeling regulations 3 Sources 4 Physiology 4 1 Absorption 4 2 Metabolism and excretion 4 3 Factors that affect biotin requirements 5 Biosynthesis 6 Cofactor biochemistry 7 Deficiency 7 1 Diagnosis 7 2 Deficiency as a result of metabolic disorders 8 Use in biotechnology 9 Interference with medical laboratory results 10 History 11 Research 11 1 Multiple sclerosis 11 2 Hair nails skin 12 Animals 13 See also 14 References 15 External linksChemical description editBiotin is classified as a heterocyclic compound with a sulfur containing tetrahydrothiophene ring fused to a ureido group A C5 carboxylic acid side chain is appended to the former ring The ureido ring containing the N CO N group serves as the carbon dioxide carrier in carboxylation reactions 7 Biotin is a coenzyme for five carboxylase enzymes which are involved in the catabolism of amino acids and fatty acids synthesis of fatty acids and gluconeogenesis 3 4 Biotinylation of histone proteins in nuclear chromatin plays a role in chromatin stability and gene expression 4 8 Dietary recommendations editThe US National Academy of Medicine updated Dietary Reference Intakes for many vitamins in 1998 At that time there was insufficient information to establish estimated average requirement or recommended dietary allowance terms that exist for most vitamins In instances such as this the academy sets adequate intakes AIs with the understanding that at some later date when the physiological effects of biotin are better understood AIs will be replaced by more exact information The biotin AIs for both males and females are 5 mg day of biotin for 0 to 6 month olds 6 mg day of biotin for 7 to 12 month olds 8 mg day of biotin for 1 to 3 year olds 12 mg day of biotin for 4 to 8 year olds 20 mg day of biotin for 9 to 13 year olds 25 mg day of biotin for 14 to 18 year olds and 30 mg day of biotin for those 19 years old and older The biotin AIs for females who are either pregnant or lactating respectively are 30 mg day of biotin for pregnant females 14 to 50 years old and 35 mg day of biotin for lactating females 14 to 50 years old 2 Australia and New Zealand set AIs similar to the US 9 The European Food Safety Authority EFSA also identifies AIs setting values at 40 mg day for adults pregnancy at 40 mg day and breastfeeding at 45 mg day For children ages 1 17 years the AIs increase with age from 20 to 35 mg day 10 Safety edit The US National Academy of Medicine estimates upper limits for vitamins and minerals when evidence for a true limit is sufficient For biotin however there is no upper limit because adverse effects of high biotin intake have not been determined 2 The EFSA also reviewed safety and reached the same conclusion as in the United States 11 Labeling regulations edit For US food and dietary supplement labeling purposes the amount in a serving is expressed as a percent of daily value For biotin labeling purposes 100 of the daily value was 300 mg day but as of May 27 2016 it was revised to 30 mg day to bring it into an agreement with the adequate intake 12 13 Compliance with the updated labeling regulations was required by January 1 2020 for manufacturers with US 10 million or more in annual food sales and by January 1 2021 for manufacturers with lower volume food sales 14 15 A table of the old and new adult daily values is provided at Reference Daily Intake Sources editSource 16 Amount mg 100 g Chicken liver 187 Beef liver 42 Eggs 21 Egg white 5 8 Egg yolk 27 Salmon canned in water 5 9 Pork chop 4 5 Turkey breast 0 7 Tuna white canned 0 7 Source 16 Amount mg 100 g Peanuts roasted 17 5 Sunflower seeds roasted 7 8 Almonds roasted 4 4 Sweet potato 1 5 Broccoli 0 9 Tomato 0 7 Strawberry 1 5 Avocado 1 0 Corn canned 0 05 Source 16 Amount mg 100 g Cheese 1 4 Milk 0 1 Oatmeal 0 1 Bread 0 1 French fries 0 3 Wine 0 1 Beer 0 1 Potatoes mashed 0 1 Biotin is stable at room temperature and is not destroyed by cooking The dietary biotin intake in Western populations has been estimated to be in the range of 35 to 70 mg day Nursing infants ingest about 6 mg day 4 Biotin is available in dietary supplements individually or as an ingredient in multivitamins 1 3 According to the Global Fortification Data Exchange biotin deficiency is so rare that no countries require that foods be fortified 17 Physiology editBiotin is a water soluble B vitamin Consumption of large amounts as a dietary supplement results in absorption followed by excretion into urine as biotin Consumption of biotin as part of a normal diet results in urinary excretion of biotin and biotin metabolites 4 Absorption edit Biotin in food is bound to proteins Digestive enzymes reduce the proteins to biotin bound peptides The intestinal enzyme biotinidase found in pancreatic secretions and in the brush border membranes of all three parts of the small intestine frees biotin which is then absorbed from the small intestine 4 When consumed as a biotin dietary supplement absorption is nonsaturable meaning that even very high amounts are absorbed effectively Transport across the jejunum is faster than across the ileum 4 The large intestine microbiota synthesize amounts of biotin estimated to be similar to the amount taken in the diet and a significant portion of this biotin exists in the free protein unbound form and thus is available for absorption How much is absorbed in humans is unknown although a review did report that human epithelial cells of the colon in vitro demonstrated an ability to uptake biotin 18 Once absorbed sodium dependent multivitamin transporter SMVT mediates biotin uptake into the liver 4 SMVT also binds pantothenic acid so high intakes of either of these vitamins can interfere with transport of the other 19 Metabolism and excretion edit Biotin catabolism occurs via two pathways In one the valeric acid sidechain is cleaved resulting in bisnorbiotin In the other pathway the sulfur is oxidized resulting in biotin sulfoxide Urine content is proportionally about half biotin plus bisnorbiotin biotin sulfoxide and small amounts of other metabolites 4 Factors that affect biotin requirements edit Chronic alcohol use is associated with a significant reduction in plasma biotin 20 Intestinal biotin uptake also appears to be sensitive to the effect of the anti epilepsy drugs carbamazepine and primidone 20 Relatively low levels of biotin have also been reported in the urine or plasma of patients who have had a partial gastrectomy or have other causes of achlorhydria as well as burn patients elderly individuals and athletes 21 Pregnancy and lactation may be associated with an increased demand for biotin In pregnancy this may be due to a possible acceleration of biotin catabolism whereas in lactation the higher demand has yet to be elucidated Recent studies have shown marginal biotin deficiency can be present in human gestation as evidenced by increased urinary excretion of 3 hydroxyisovaleric acid decreased urinary excretion of biotin and bisnorbiotin and decreased plasma concentration of biotin 4 Biosynthesis editBiotin synthesized in plants is essential to plant growth and development 22 Bacteria also synthesize biotin 23 and it is thought that bacteria resident in the large intestine may synthesize biotin that is absorbed and utilized by the host organism 18 Biosynthesis starts from two precursors alanine and pimeloyl CoA These form 7 keto 8 aminopelargonic acid KAPA KAPA is transported from plant peroxisomes to mitochondria where it is converted to 7 8 diaminopelargonic acid DAPA with the help of the enzyme BioA The enzyme dethiobiotin synthetase catalyzes the formation of the ureido ring via a DAPA carbamate activated with ATP creating dethiobiotin with the help of the enzyme BioD which is then converted into biotin which is catalyzed by BioB 24 The last step is catalyzed by biotin synthase a radical SAM enzyme The sulfur is donated by an unusual 2Fe 2S ferredoxin 25 Depending on the species of bacteria Biotin can be synthesized via multiple pathways 24 Cofactor biochemistry editThe enzyme holocarboxylase synthetase covalently attaches biotin to five human carboxylase enzymes 4 Acetyl CoA carboxylase alpha ACC1 Acetyl CoA carboxylase beta ACC2 Pyruvate carboxylase PC Methylcrotonyl CoA carboxylase MCC Propionyl CoA carboxylase PCC For the first two biotin serves as a cofactor responsible for transfer of bicarbonate to acetyl CoA converting it to malonyl CoA for fatty acid synthesis PC participates in gluconeogenesis MCC catalyzes a step in leucine metabolism PCC catalyzes a step in the metabolism of propionyl CoA 1 3 4 Metabolic degradation of the biotinylated carboxylases leads to the formation of biocytin This compound is further degraded by biotinidase to release biotin which is then reutilized by holocarboxylase synthetase 4 Biotinylation of histone proteins in nuclear chromatin is a posttranslational modification that plays a role in chromatin stability and gene expression 4 8 Deficiency editMain article Biotin deficiency Primary biotin deficiency meaning deficiency as a consequence of too little biotin in the diet is rare because biotin is contained in so many foods Subclinical deficiency can cause mild symptoms such as hair thinning brittle fingernails or skin rash typically on the face 2 4 Aside from inadequate dietary intake rare deficiency of biotin can be caused by a genetic disorder that affects biotin metabolism The most common among these is biotinidase deficiency Low activity of this enzyme causes a failure to recycle biotin from biocytin Rarer are carboxylase and biotin transporter deficiences 4 26 Neonatal screening for biotinidase deficiency started in the United States in 1984 with many countries now also testing for this genetic disorder at birth Treatment is lifelong dietary supplement with biotin 1 If biotinidase deficiency goes untreated it can be fatal 27 Diagnosis edit Low serum and urine biotin are not sensitive indicators of inadequate biotin intake 4 However serum testing can be useful for confirmation of consumption of biotin containing dietary supplements and whether a period of refraining from supplement use is long enough to eliminate the potential for interfering with drug tests 28 29 Indirect measures depend on the biotin requirement for carboxylases 3 Methylcrotonyl CoA is an intermediate step in the catabolism of the amino acid leucine In the absence of biotin the pathway diverts to 3 hydroxyisovaleric acid Urinary excretion of this compound is an early and sensitive indicator of biotin deficiency 2 4 Deficiency as a result of metabolic disorders edit Biotinidase deficiency is a deficiency of the enzyme that recycles biotin the consequence of an inherited genetic mutation 1 Biotinidase catalyzes the cleavage of biotin from biocytin and biotinyl peptides the proteolytic degradation products of each holocarboxylase and thereby recycles biotin 2 It is also important in freeing biotin from dietary protein bound biotin 30 Neonatal screening for biotinidase deficiency started in the United States in 1984 31 which as of 2017 was reported as required in more than 30 countries 32 Profound biotinidase deficiency defined as less than 10 of normal serum enzyme activity which has been reported as 7 1 nmol min mL has an incidence of 1 in 40 000 to 1 in 60 000 but with rates as high as 1 in 10 000 in countries with high incidence of consanguineous marriages second cousin or closer Partial biotinidase deficiency is defined as 10 to 30 of normal serum activity 31 Incidence data stems from government mandated newborn screening 32 For profound deficiency treatment is oral dosing with 5 to 20 mg per day Seizures are reported as resolving in hours to days with other symptoms resolving within weeks 31 Treatment of partial biotinidase deficiency is also recommended even though some untreated people never manifest symptoms 31 Lifelong treatment with supplemental biotin is recommended for both profound and partial biotinidase deficiency 1 Inherited metabolic disorders characterized by deficient activities of biotin dependent carboxylases are termed multiple carboxylase deficiency These include deficiencies in the enzymes holocarboxylase synthetase 1 Holocarboxylase synthetase deficiency prevents the body s cells from using biotin effectively and thus interferes with multiple carboxylase reactions 30 There can also be a genetic defect affecting the sodium dependent multivitamin transporter protein 26 Biochemical and clinical manifestations of any of these metabolic disorders can include ketolactic acidosis organic aciduria hyperammonemia rash hypotonia seizures developmental delay alopecia and coma 4 Use in biotechnology editChemically modified versions of biotin are widely used throughout the biotechnology industry to isolate proteins and non protein compounds for biochemical assays 33 Because egg derived avidin binds strongly to biotin with a dissociation constant Kd 10 15 M 34 biotinylated compounds of interest can be isolated from a sample by exploiting this highly stable interaction First the chemically modified biotin reagents are bound to the targeted compounds in a solution via a process called biotinylation The choice of which chemical modification to use is responsible for the biotin reagent binding to a specific protein 33 Second the sample is incubated with avidin bound to beads then rinsed removing all unbound proteins while leaving only the biotinylated protein bound to avidin Last the biotinylated protein can be eluted from the beads with excess free biotin 35 The process can also utilize bacteria derived streptavidin bound to beads but because it has a higher dissociation constant than avidin very harsh conditions are needed to elute the biotinylated protein from the beads which often will denature the protein of interest 34 Interference with medical laboratory results editWhen people are ingesting high levels of biotin in dietary supplements a consequence can be clinically significant interference with diagnostic blood tests that use biotin streptavidin technology This methodology is commonly used to measure levels of hormones such as thyroid hormones and other analytes such as 25 hydroxyvitamin D Biotin interference can produce both falsely normal and falsely abnormal results 1 36 In the US biotin as a non prescription dietary supplement is sold in amounts of 1 to 10 mg per serving with claims for supporting hair and nail health and as 300 mg per day as a possibly effective treatment for multiple sclerosis 37 38 see Research Overconsumption of 5 mg day or higher causes elevated concentration in plasma that interferes with biotin streptavidin immunoassays in an unpredictable manner 28 29 Healthcare professionals are advised to instruct patients to stop taking biotin supplements for 48 h or even up to weeks before the test depending on the specific test dose and frequency of biotin uptake 28 Guidance for laboratory staff is proposed to detect and manage biotin interference 29 History editFurther information Vitamin History In 1916 W G Bateman observed that a diet high in raw egg whites caused toxic symptoms in dogs cats rabbits and humans 39 By 1927 scientists such as Margarete Boas and Helen Parsons had performed experiments demonstrating the symptoms associated with egg white injury They had found that rats fed large amounts of egg white as their only protein source exhibited neurological dysfunction hair loss dermatitis and eventually death 40 41 In 1936 Fritz Kogl and Benno Tonnis documented isolating a yeast growth factor in a journal article titled Darstellung von krystallisiertem biotin aus eigelb Representation of crystallized biotin from egg yolk 42 The name biotin derives from the Greek word bios to live and the suffix in a general chemical suffix used in organic chemistry 5 Other research groups working independently had isolated the same compound under different names Hungarian scientist Paul Gyorgy began investigating the factor responsible for egg white injury in 1933 and in 1939 was successful identifying what he called Vitamin H the H represents Haar und Haut German for hair and skin 43 44 Further chemical characterization of vitamin H revealed that it was water soluble and present in high amounts in the liver 45 After experiments performed with yeast and Rhizobium trifolii West and Wilson isolated a compound they called co enzyme R 46 47 By 1940 it was recognized that all three compounds were identical and were collectively given the name biotin 48 Gyorgy continued his work on biotin and in 1941 published a paper demonstrating that egg white injury was caused by the binding of biotin by avidin 49 50 Unlike for many vitamins there is insufficient information to establish a recommended dietary allowance so dietary guidelines identify an adequate intake based on best available science with the understanding that at some later date this will be replaced by more exact information 2 9 10 Using E coli a biosynthesis pathway was proposed by Rolfe and Eisenberg in 1968 The initial step was described as a condensation of pimelyl CoA and alanine to form 7 oxo 8 aminopelargonic acid From there they described three step process the last being introducing a sulfur atom to form the tetrahydrothiophene ring 51 Research editMultiple sclerosis edit High dose biotin 300 mg day 10 000 times adequate intake has been used in clinical trials for treatment of multiple sclerosis a demyelinating autoimmune disease 37 38 The hypothesis is that biotin may promote remyelination of the myelin sheath of nerve cells slowing or even reversing neurodegeneration The proposed mechanisms are that biotin activates acetyl coA carboxylase which is a key rate limiting enzyme during the synthesis of myelin and by reducing axonal hypoxia through enhanced energy production 37 38 Clinical trial results are mixed a 2019 review concluded that a further investigation of the association between multiple sclerosis symptoms and biotin should be undertaken 37 whereas two 2020 reviews of a larger number of clinical trials reported no consistent evidence for benefits 52 and some evidence for increased disease activity and higher risk of relapse 53 Hair nails skin edit In the United States biotin is promoted as a dietary supplement for strengthening hair and fingernails though scientific data supporting these outcomes in humans are very weak 3 54 55 A review of the fingernails literature reported brittle nail improvement as evidence from two pre 1990 clinical trials that had administered an oral dietary supplement of 2 5 mg day for several months without a placebo control comparison group There is no more recent clinical trial literature 54 A review of biotin as treatment for hair loss identified case studies of infants and young children with genetic defect biotin deficiency having improved hair growth after supplementation but went on to report that there have been no randomized controlled trials to prove efficacy of supplementation with biotin in normal healthy individuals 55 Biotin is also incorporated into topical hair and skin products with similar claims 56 The Dietary Supplement Health and Education Act of 1994 states that the US Food and Drug Administration must allow on the product label what are described as Structure Function S F health claims that ingredient s are essential for health For example Biotin helps maintain healthy skin hair and nails If a S F claim is made the label must include the disclaimer This statement has not been evaluated by the Food and Drug Administration This product is not intended to diagnose treat cure or prevent any disease 57 Animals editIn cattle biotin is necessary for hoof health Lameness due to hoof problems is common with herd prevalence estimated at 10 to 35 citation needed Consequences of lameness include less food consumption lower milk production and increased veterinary treatment costs Results after 4 6 months from supplementing biotin at 20 mg day into daily diet reduces the risk of lameness 58 59 A review of controlled trials reported that supplementation at 20 mg day increased milk yield by 4 8 The discussion speculated that this could be an indirect consequence of improved hoof health or a direct effect on milk production 60 For horses conditions such as chronic laminitis cracked hooves or dry brittle feet incapable of holding shoes are a common problem Biotin is a popular nutritional supplement There are recommendations that horses need 15 to 25 mg day Studies report biotin improves the growth of new hoof horn rather than improving the status of existing hoof so months of supplementation are needed for the hoof wall to be completely replaced 61 See also editBiotin deficiency Biotin sulfoxide Biotinidase deficiency Biotinylation Multiple carboxylase deficiency NeutrAvidin PhotobiotinReferences edit a b c d e f g h Biotin Fact Sheet for Health Professionals Office of Dietary Supplements US National Institutes of Health December 8 2017 Archived from the original on April 14 2020 Retrieved February 25 2018 a b c d e f g Institute of Medicine 1998 Biotin Dietary Reference Intakes for Thiamin Riboflavin Niacin Vitamin B6 Folate Vitamin B12 Pantothenic Acid Biotin and Choline Washington DC The National Academies Press pp 374 389 ISBN 0 309 06554 2 Archived from the original on July 17 2015 Retrieved August 29 2017 a b c d e Biotin Micronutrient Information Center Linus Pauling Institute Oregon State University Corvallis OR October 21 2015 Archived from the original on January 18 2018 Retrieved January 16 2018 a b c d e f g h i j k l m n o p q r s Penberthy WT Sadri M Zempleni J 2020 Biotin In BP Marriott DF Birt VA Stallings AA Yates eds Present Knowledge in Nutrition Eleventh Edition London United Kingdom Academic Press Elsevier pp 289 304 ISBN 978 0 323 66162 1 a b biotin Origin and meaning of biotin by Online Etymology Dictionary www etymonline com Archived from the original on August 22 2020 Retrieved November 14 2020 Anonymous PubChem Compound Summary for CID 171548 Biotin https pubchem ncbi nlm nih gov compound 171548 Archived August 6 2023 at the Wayback Machine accessed Oct 19 2023 Waldrop GL Holden HM St Maurice M November 2012 The Enzymes of Biotin dependent CO Metabolism What Structures Reveal about Their Reaction Mechanisms Protein Science 21 11 1597 1619 doi 10 1002 pro 2156 PMC 3527699 PMID 22969052 a b Xu YM Du JY Lau AT September 2014 Posttranslational modifications of human histone H3 an update Proteomics 14 17 18 2047 2060 doi 10 1002 pmic 201300435 PMID 25044606 S2CID 11293428 a b National Health and Medical Research Council Nutrient Reference Values for Australia and New Zealand PDF Archived from the original PDF on January 21 2017 Retrieved February 19 2010 a b Overview on Dietary Reference Values for the EU population as derived by the EFSA Panel on Dietetic Products Nutrition and Allergies PDF 2017 Archived PDF from the original on August 28 2017 Retrieved August 30 2017 Tolerable Upper Intake Levels For Vitamins And Minerals PDF European Food Safety Authority 2006 Archived PDF from the original on March 16 2016 Retrieved March 4 2016 Federal Register May 27 2016 Food Labeling Revision of the Nutrition and Supplement Facts Labels PDF Archived PDF from the original on September 22 2017 Daily Value Reference of the Dietary Supplement Label Database DSLD Dietary Supplement Label Database DSLD Archived from the original on April 7 2020 Retrieved May 16 2020 Changes to the Nutrition Facts Label U S Food and Drug Administration FDA May 27 2016 Archived from the original on May 6 2018 Retrieved May 16 2020 nbsp This article incorporates text from this source which is in the public domain Industry Resources on the Changes to the Nutrition Facts Label U S Food and Drug Administration FDA December 21 2018 Archived from the original on December 25 2020 Retrieved May 16 2020 nbsp This article incorporates text from this source which is in the public domain a b c Staggs CG Sealey WM McCabe BJ Teague AM Mock DM December 2004 Determination of the biotin content of select foods using accurate and sensitive HPLC avidin binding Journal of Food Composition and Analysis 17 6 767 76 doi 10 1016 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