Histidine
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| Names | |||
|---|---|---|---|
| IUPAC name
Histidine | |||
| Other names
2-Amino-3-(1H-imidazol-4-yl)propanoic acid | |||
| Identifiers | |||
71-00-1  | |||
| ChEBI | CHEBI:57595 | ||
| ChEMBL | ChEMBL17962 | ||
| ChemSpider | 6038 | ||
| DrugBank | DB00117 | ||
| 3310 | |||
| Jmol 3D model | Interactive image Interactive image | ||
| KEGG | D00032 | ||
| PubChem | 773 | ||
| UNII | 4QD397987E | ||
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| Properties | |||
| C6H9N3O2 | |||
| Molar mass | 155.16 g·mol−1 | ||
| 4.19g/100g @ 25 °C [1] | |||
| Hazards | |||
| Safety data sheet | See: data page | ||
| NFPA 704 | |||
| Supplementary data page | |||
| Refractive index (n), Dielectric constant (εr), etc. | |||
| Thermodynamic data |
Phase behaviour solid–liquid–gas | ||
| UV, IR, NMR, MS | |||
verify (what is  ?) | |||
| Infobox references | |||
Histidine (abbreviated as His or H; encoded by the codons CAU and CAC) is an α-amino acid that is used in the biosynthesis of proteins. It contains an α-amino group (which is in the protonated –NH3+ form under biological conditions), a carboxylic acid group (which is in the deprotonated –COO− form under biological conditions), and a side chain imidazole, classifying it as a positively charged (at physiological pH). Initially thought essential only for infants, longer-term studies have shown it is essential for adults also.[2]
Histidine was first isolated by German physician Albrecht Kossel and Sven Hedin in 1896.[3] It is also a precursor to histamine, a vital inflammatory agent in immune responses.
Chemical properties
The conjugate acid (protonated form) of the imidazole side chain in histidine has a pKa of approximately 6.0. This means that, at physiologically relevant pH values, relatively small shifts in pH will change its average charge. Below a pH of 6, the imidazole ring is mostly protonated as described by the Henderson–Hasselbalch equation. When protonated, the imidazole ring bears two NH bonds and has a positive charge. The positive charge is equally distributed between both nitrogens and can be represented with two equally important resonance structures. As the pH increases past approximately 6, one of the protons is lost. The remaining proton of the now-neutral imidazole ring can reside on either nitrogen, giving rise to what are known as the N1-H or N3-H tautomers. The N3-H tautomer, shown in the figure above, is protonated on the #3 nitrogen, farther from the amino acid backbone bearing the amino and carboxyl groups, whereas the N1-H tautomer is protonated on the nitrogen nearer the backbone.
Aromaticity
The imidazole ring of histidine is aromatic at all pH values.[4] It contains six pi electrons: four from two double bonds and two from a nitrogen lone pair. It can form pi stacking interactions,[5] but is complicated by the positive charge.[6] It does not absorb at 280 nm in either state, but does in the lower UV range more than some amino acids.[7][8]
Biochemistry
The imidazole sidechain of histidine is a common coordinating ligand in metalloproteins and is a part of catalytic sites in certain enzymes. In catalytic triads, the basic nitrogen of histidine is used to abstract a proton from serine, threonine, or cysteine to activate it as a nucleophile. In a histidine proton shuttle, histidine is used to quickly shuttle protons. It can do this by abstracting a proton with its basic nitrogen to make a positively charged intermediate and then use another molecule, a buffer, to extract the proton from its acidic nitrogen. In carbonic anhydrases, a histidine proton shuttle is utilized to rapidly shuttle protons away from a zinc-bound water molecule to quickly regenerate the active form of the enzyme. Histidine is also important in haemoglobin in helices E and F. Histidine assists in stabilising oxyhaemoglobin and destabilising CO-bound haemoglobin. As a result, carbon monoxide binding is only 200 times stronger in haemoglobin, compared to 20,000 times stronger in free haem.
Certain amino acids can be converted to intermediates of the TCA cycle. Carbons from four groups of amino acids form the TCA cycle intermediates α-ketoglutarate, succinyl CoA, fumarate, and oxaloacetate. Amino acids that form α-ketoglutarate are glutamate, glutamine, proline, arginine, and histidine. Histidine is converted to formiminoglutamate (FIGLU). The formimino group is transferred to tetrahydrofolate, and the remaining five carbons form glutamate. Glutamate can be deaminated by glutamate dehydrogenase or transaminated to form α-ketoglutarate.[9]
NMR and tautomerism
When both imidazole ring nitrogens are protonated, their 15N chemical shifts are similar (about 200 ppm, relative to nitric acid on the sigma scale, on which increased shielding corresponds to increased chemical shift). NMR shows that the chemical shift of N1-H drops slightly, whereas the chemical shift of N3-H drops considerably (about 190 vs. 145 ppm). This indicates that the N1-H tautomer is preferred, it is presumed due to hydrogen bonding to the neighboring ammonium. The shielding at N3 is substantially reduced due to the second-order paramagnetic effect, which involves a symmetry-allowed interaction between the nitrogen lone pair and the excited π* states of the aromatic ring. As the pH rises above 9, the chemical shifts of N1 and N3 become approximately 185 and 170 ppm. An entirely deprotonated form of the imidazole ring, the imidazolate ion, would be formed only above a pH of 14, and is therefore not physiologically relevant. This change in chemical shifts can be explained by the presumably decreased hydrogen bonding of an amine over an ammonium ion, and the favorable hydrogen bonding between a carboxylate and an NH. This should act to decrease the N1-H tautomer preference.[10]
Metabolism
Biosynthesis
As an essential amino acid, histidine is not synthesized de novo in humans and other animals, who must ingest histidine or histidine-containing proteins. In microorganisms and plants it is synthesized in several steps from the common biochemical intermediate phosphoribosyl pyrophosphate.[11] Histidine can be found in hemoglobin and myelin sheets. [12]
Catabolism
The amino acid is a precursor for histamine and carnosine biosynthesis.
The enzyme histidine ammonia-lyase converts histidine into ammonia and urocanic acid. A deficiency in this enzyme is present in the rare metabolic disorder histidinemia, producing urocanic aciduria as a key diagnostic symptom. In Actinobacteria and filamentous fungi, such as Neurospora crassa, histidine can be converted into the antioxidant ergothioneine.[13]
Supplementation
Supplementation of histidine has been shown to cause rapid zinc excretion in rats with an excretion rate 3 to 6 times normal.[14][15]
See also
References
- ↑ http://prowl.rockefeller.edu/aainfo/solub.htm[]
- ↑ Kopple, J D; Swendseid, M E (1975). "Evidence that histidine is an essential amino acid in normal and chronically uremic man". Journal of Clinical Investigation 55 (5): 881–91. doi:10.1172/JCI108016. PMC 301830. PMID 1123426.
- ↑ Vickery, Hubert Bradford; Leavenworth, Charles S. (1928-08-01). "ON THE SEPARATION OF HISTIDINE AND ARGININE IV. THE PREPARATION OF HISTIDINE". Journal of Biological Chemistry 78 (3): 627–635. ISSN 0021-9258.
- ↑ Mrozek, Agnieszka; Karolak-Wojciechowska, Janina; Kieć-Kononowicz, Katarzyna (2003). "Five-membered heterocycles. Part III. Aromaticity of 1,3-imidazole in 5+n hetero-bicyclic molecules". Journal of Molecular Structure 655 (3): 397–403. Bibcode:2003JMoSt.655..397M. doi:10.1016/S0022-2860(03)00282-5.
- ↑ Wang, Lijun; Sun, Na; Terzyan, Simon; Zhang, Xuejun; Benson, David R. (2006). "A Histidine/Tryptophan π-Stacking Interaction Stabilizes the Heme-Independent Folding Core of Microsomal Apocytochrome b5Relative to that of Mitochondrial Apocytochrome b5". Biochemistry 45 (46): 13750–9. doi:10.1021/bi0615689. PMID 17105194.
- ↑ Blessing, Robert H.; McGandy, Edward L. (1972). "Base stacking and hydrogen bonding in crystals of imidazolium dihydrogen orthophosphate". Journal of the American Chemical Society 94 (11): 4034–4035. doi:10.1021/ja00766a075.
- ↑ Katoh, Ryuzi (2007). "Absorption Spectra of Imidazolium Ionic Liquids". Chemistry Letters 36 (10): 1256–1257. doi:10.1246/cl.2007.1256.
- ↑ A. Robert Goldfarb; Saidel, LJ; Mosovich, E (1951-11-01). "The Ultraviolet Absorption Spectra of Proteins". Journal of Biological Chemistry 193 (1): 397–404. PMID 14907727.
- ↑ Board review series (BRS)-- Biochemistry, Molecular Biology, and Genetics (fifth edition): Swanson, Kim, Glucksman
- ↑ Roberts, John D. (2000). ABCs of FT-NMR. Sausalito, CA: University Science Books. pp. 258–9. ISBN 978-1-891389-18-4.
- ↑ Roche Biochemical Pathways Map Roche biochemical pathways map
- ↑ Pubchem. "L-histidine | C6H9N3O2 - PubChem". pubchem.ncbi.nlm.nih.gov. Retrieved 2016-04-28.
- ↑ Fahey, Robert C. (2001). "Novelthiols Ofprokaryotes". Annual Review of Microbiology 55: 333–56. doi:10.1146/annurev.micro.55.1.333. PMID 11544359.
- ↑ R M Freeman; Taylor, PR (1977-04-01). "Influence of histidine administration on zinc metabolism in the rat". The American Journal of Clinical Nutrition 30 (4): 523–7. PMID 851080.
- ↑ Wensink, Jan; Hamer, Cornelis J. A. (1988). "Effect of excess dietary histidine on rate of turnover of65Zn in brain of rat". Biological Trace Element Research 16 (2): 137–50. doi:10.1007/BF02797098. PMID 2484542.
External links
- Histidine MS Spectrum
- Histidine biosynthesis (early stages)
- Histidine biosynthesis (later stages)
- Histidine catabolism
- Food Sources of Histidine
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