Phytic acid

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Phytic acid

Names
IUPAC name (1R,2S,3r,4R,5S,6s)-cyclohexane-1,2,3,4,5,6-hexayl hexakis[dihydrogen (phosphate)]
Identifiers
CAS Number	83-86-3
3D model (JSmol)	Interactive image
ChEBI	CHEBI:17401
ChemSpider	16735966
ECHA InfoCard	100.001.369
E number	E391 (antioxidants, ...)
PubChem CID	890
UNII	7IGF0S7R8I
InChI[show]
SMILES[show]
Properties
Chemical formula	C6H18O24P6
Molar mass	660.029 g·mol−1
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
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Infobox references

Phytic acid is a six-fold dihydrogenphosphate ester of inositol (specifically, of the myo isomer), also called inositol hexakisphosphate (IP6) or inositol polyphosphate. At physiological pH, the phosphates are partially ionized, resulting in the phytate anion.

The (myo) phytate anion is a colorless species that has significant nutritional role as the principal storage form of phosphorus in many plant tissues, especially bran and seeds.^[1] It is also present in many legumes, cereals, and grains.^[1] Phytic acid and phytate have a strong binding affinity to the dietary minerals, calcium, iron, and zinc, inhibiting their absorption.^[1]

The lower inositol polyphosphates are inositol esters with less than six phosphates, such as inositol penta- (IP5), tetra- (IP4), and triphosphate (IP3). These occur in nature as catabolites of phytic acid.

Contents

• 1 Significance in agriculture
• 2 Biological and physiological roles
• 3 Food science
  • 3.1 Dietary mineral absorption
  • 3.2 Human nutrition
• 4 See also
• 5 References

Significance in agriculture

 

Phosphorus and inositol in phytate form are not, in general, bioavailable to nonruminant animals because these animals lack the digestive enzyme phytase required to hydrolyze (break) the inositol-phosphate linkages. Ruminants are readily able to digest phytate because of the phytase produced by rumen microorganisms.^[2]

In most commercial agriculture, non-ruminant livestock, such as swine, fowl, and fish,^[3] are fed mainly grains, such as maize, legumes, and soybeans.^{[citation needed]} Because phytate from these grains and beans is unavailable for absorption, the unabsorbed phytate passes through the gastrointestinal tract, elevating the amount of phosphorus in the manure.^[2] Excess phosphorus excretion can lead to environmental problems, such as eutrophication.^[4] The use of sprouted grains will reduce the quantity of phytic acids in feed, with no significant reduction of nutritional value.^[5]

Also, viable low-phytic acid mutant lines have been developed in several crop species in which the seeds have drastically reduced levels of phytic acid and concomitant increases in inorganic phosphorus.^[6] However, germination problems have reportedly hindered the use of these cultivars thus far. This may be due to phytic acid's critical role in both phosphorus and metal ion storage.^{[citation needed]} Phytate variants also have the potential to be used in soil remediation, to immobilize uranium, nickel and other inorganic contaminants.^[7]

Biological and physiological roles

Although indigestible for many animals, phytic acid and its metabolites as they occur in seeds and grains have several important roles for the seedling plant.

Most notably, phytic acid functions as a phosphorus store, as an energy store, as a source of cations and as a source of myoinositol (a cell wall precursor). Phytic acid is the principal storage form of phosphorus in plant seeds.^[8]

In animal cells, myoinositol polyphosphates are ubiquitous, and phytic acid (myoinositol hexakisphosphate) is the most abundant, with its concentration ranging from 10 to 100 μM in mammalian cells, depending on cell type and developmental stage.^[9][10]

This compound is not obtained from the animal diet, but must be synthesized inside the cell from phosphate and inositol (which in turn is produced from glucose, usually in the kidneys). The interaction of intracellular phytic acid with specific intracellular proteins has been investigated in vitro, and these interactions have been found to result in the inhibition or potentiation of the physiological activities of those proteins.^[11][12] The best evidence from these studies suggests an intracellular role for phytic acid as a cofactor in DNA repair by nonhomologous end-joining.^[11] Other studies using yeast mutants have also suggested intracellular phytic acid may be involved in mRNA export from the nucleus to the cytosol.^[13][14]

Inositol hexaphosphate facilitates the formation of the six-helix bundle and assembly of the immature HIV-1 Gag lattice. IP6 makes ionic contacts with two rings of lysine residues at the centre of the Gag hexamer. Proteolytic cleavage then unmasks an alternative binding site, where IP6 interaction promotes the assembly of the mature capsid lattice. These studies identify IP6 as a naturally occurring small molecule that promotes both assembly and maturation of HIV-1.^[15]

Food science

Phytic acid was discovered in 1903.^[16] Phytic acid, mostly as phytate in the form of phytin, is found within the hulls of seeds, including nuts, grains and pulses.^[1] In-home food preparation techniques can break down the phytic acid in all of these foods. Simply cooking the food will reduce the phytic acid to some degree. More effective methods are soaking in an acid medium, sprouting and lactic acid fermentation such as in sourdough and pickling.^[17] No detectable phytate (less than 0.02% of wet weight) was observed in vegetables such as scallion and cabbage leaves or in fruits such as apples, oranges, bananas, or pears.^[18]

As a food additive, phytic acid is used as the preservative, E391.^[19][20]

Food sources of phytic acid (g/100 g) ^{[21] [18] [22][23][24][25][26][27]}

Food	[% minimum dry]	[% maximum dry]
Pumpkin seed	4.3	4.3
Linseed	2.15	2.78
Sesame seeds flour	5.36	5.36
Chia seeds	0.96	1.16
Almonds	1.35	3.22
Brazil nuts	1.97	6.34
Coconut	0.36	0.36
Hazelnut	0.65	0.65
Peanut	0.95	1.76
Walnut	0.98	0.98
Maize (Corn)	0.75	2.22
Oat	0.42	1.16
Oat Meal	0.89	2.40
Brown rice	0.84	0.99
Polished rice	0.14	0.60
Wheat	0.39	1.35
Wheat flour	0.25	1.37
Wheat germ	0.08	1.14
Whole wheat bread	0.43	1.05
Beans, pinto	2.38	2.38
Buckwheat	1.00	1.00
Chickpeas	0.56	0.56
Lentils	0.44	0.50
Soybeans	1.00	2.22
Tofu	1.46	2.90
Soy beverage	1.24	1.24
Soy protein concentrate	1.24	2.17
New potato	0.18	0.34
Spinach	0.22	NR
Avocado fruit	0.51	0.51

Food sources of phytic acid (fresh weight)^[23]

Food	[% minimum fresh weight]	[% maximum fresh weight]
Taro	0.143	0.195
Cassava	0.114	0.152

Chestnuts contain 47 mg of phytic acid for 100 g.^[28]

Dietary mineral absorption

Phytic acid has a strong binding affinity to the dietary minerals, calcium, iron, and zinc, inhibiting their absorption.^[1][29] Phytochemicals like polyphenols and tannins also influence the binding.^[30] When iron and zinc bind to phytic acid, they form insoluble precipitates and are far less absorbable in the intestines. This process can therefore contribute to iron and zinc deficiencies in people whose diets rely on these foods for their mineral intake, such as those in developing countries^[31][32] and vegetarians.^[33]

Human nutrition

Because phytic acid can affect the absorption of iron, it has been proposed that "dephytinization should be considered as a major strategy to improve iron nutrition during the weaning period".^[34]

See also

Wikimedia Commons has media related to Phytic acid.

• Antinutrient
• Essential nutrient
• Oxalic acid

References

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• Klopfenstein TJ, Angel R, Cromwell G, Erickson GE, Fox DG, Parsons C, Satter LD, Sutton AL, Baker DH (July 2002). "Animal Diet Modification to Decrease the Potential for Nitrogen and Phosphorus Pollution". Council for Agricultural Science and Technology. 21.
• Romarheim OH, Zhang C, Penn M, Liu YJ, Tian LX, Skrede A, Krogdahl Å, Storebakken T (2008). "Growth and intestinal morphology in cobia (Rachycentron canadum) fed extruded diets with two types of soybean meal partly replacing fish meal". Aquaculture Nutrition. 14 (2): 174–180. doi:10.1111/j.1365-2095.2007.00517.x.
• Mallin MA (2003). "Industrialized Animal Production—A Major Source of Nutrient and Microbial Pollution to Aquatic Ecosystems". Population and Environment. 24 (5): 369–385. doi:10.1023/A:1023690824045. JSTOR 27503850.
• Malleshi, N. G.; Desikachar, H. S. R. (1986). "Nutritive value of malted millet flours". Plant Foods for Human Nutrition. 36 (3): 191–6. doi:10.1007/BF01092036.
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• Seaman JC, Hutchison JM, Jackson BP, Vulava VM (2003). "In situ treatment of metals in contaminated soils with phytate". Journal of Environmental Quality. 32 (1): 153–61. doi:10.2134/jeq2003.0153. PMID 12549554.
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• Szwergold BS, Graham RA, Brown TR (December 1987). "Observation of inositol pentakis- and hexakis-phosphates in mammalian tissues by 31P NMR". Biochemical and Biophysical Research Communications. 149 (3): 874–81. doi:10.1016/0006-291X(87)90489-X. PMID 3426614.
• Sasakawa N, Sharif M, Hanley MR (July 1995). "Metabolism and biological activities of inositol pentakisphosphate and inositol hexakisphosphate". Biochemical Pharmacology. 50 (2): 137–46. doi:10.1016/0006-2952(95)00059-9. PMID 7543266.
• Hanakahi LA, Bartlet-Jones M, Chappell C, Pappin D, West SC (September 2000). "Binding of inositol phosphate to DNA-PK and stimulation of double-strand break repair". Cell. 102 (6): 721–9. doi:10.1016/S0092-8674(00)00061-1. PMID 11030616.
• Norris FA, Ungewickell E, Majerus PW (January 1995). "Inositol hexakisphosphate binds to clathrin assembly protein 3 (AP-3/AP180) and inhibits clathrin cage assembly in vitro". The Journal of Biological Chemistry. 270 (1): 214–7. doi:10.1074/jbc.270.1.214. PMID 7814377.
• York JD, Odom AR, Murphy R, Ives EB, Wente SR (July 1999). "A phospholipase C-dependent inositol polyphosphate kinase pathway required for efficient messenger RNA export". Science. 285 (5424): 96–100. doi:10.1126/science.285.5424.96. PMID 10390371.
• Shears SB (March 2001). "Assessing the omnipotence of inositol hexakisphosphate". Cellular Signalling (Submitted manuscript). 13 (3): 151–8. doi:10.1016/S0898-6568(01)00129-2. PMID 11282453.
• Dick RA, Zadrozny KK, Xu C, Schur FK, Lyddon TD, Ricana CL, Wagner JM, Perilla JR, Ganser-Pornillos BK, Johnson MC, Pornillos O, Vogt VM (August 2018). "Inositol phosphates are assembly co-factors for HIV-1". Nature. 560 (7719): 509–512. doi:10.1038/s41586-018-0396-4. PMC 6242333. PMID 30069050.
• Mullaney EJ, Ullah, Abul H.J. "Phytases: attributes, catalytic mechanisms, and applications" (PDF). United States Department of Agriculture–Agricultural Research Service. Archived from the original (PDF) on 2012-11-07. Retrieved May 18, 2012.
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• https://noshly.com/additive/391/preservative/391/
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