Record Information
Version1.0
StatusDetected and Quantified
Creation Date2020-12-10 18:35:53 UTC
Update Date2024-04-30 19:31:53 UTC
Metabolite IDMMDBc0000349
Metabolite Identification
Common Name3-Methylhistidine
Description3-Methylhistidine, also known as 3-MHis, 3MH, pi-methylhistidine or pros-methylhistidine, belongs to the class of organic compounds known as histidine and derivatives. 3MH is also classified as a methylamino acid. Methylamino acids are primarily proteogenic amino acids (found in proteins) which have been methylated (in situ) on their side chains by various methyltransferase enzymes. Histidine can be methylated at either the N1 or N3 position of its imidazole ring, yielding the isomers 1-methylhistidine (1MH; also referred to as tau-methylhistidine, according to IUPAC) or 3-methylhistidine (3MH; pi-methylhistidine, according to IUPAC), respectively. There is considerable confusion with regard to the nomenclature of the methylated nitrogen atoms on the imidazole ring of histidine in histidine-containing proteins (such as actin and myosin) as well as histidine-containing peptides (such as anserine and ophidine/balenine). In particular, older literature (mostly prior to the year 2000) as well as most biochemists and nutrition scientists incorrectly number the imidazole nitrogen atom most proximal to the side chain beta-carbon as 1 or N1, while organic chemists correctly designate it as 3 or N3. As a result, biochemists and nutrition scientists historically designated anserine (Npi-methylated) as beta-alanyl-N1-methylhistidine (or beta-alanyl-1-methylhistidine), whereas according to standard IUPAC nomenclature, anserine is correctly named as beta-alanyl-N3-methylhistidine. As a result, for several decades, many papers incorrectly identified 1MH as a specific marker for dietary consumption or various pathophysiological effects when they really are referring to 3MH – and vice versa (PMID: 24137022 ). To help resolve this issue the IUPAC commission (PMID: 6743224 and IUPAC Compendium of Chemical Terminology, 2nd ed. (the 'Gold Book'). Compiled by A. D. McNaught and A. Wilkinson. Blackwell Scientific Publications, Oxford (1997)) revised the nomenclature for histidine and introduced the terms pi (for prox or pros – near) and tau (for tele – far) to label the imidazole nitrogens in histidine. Therefore, the pi nitrogen is the nitrogen closest to the side chain beta carbon (atom #3 or N3) while the tau nitrogen is most distant from the side chain beta carbon (atom #1 or N1). IUPAC’s goal is for the global community to refer to the molecule depicted here is as “pi-methylhistidine” with the hope that the archaic term, 3-methylhistidine will eventually disappear. Unfortunately, this has not happened and confusion still persists. Older versions of the HMDB (prior to 2022) as well as current versions of some databases, such as PubChem, KEGG, and UniProt, indicate that an acceptable synonym for 3MH is tau-methylhistidine or otherwise somehow equate 1MH and 3MH. This is incorrect and it continues to sow confusion. Indeed, a key paper that identified METTL9 as the enzyme responsible for pi-methylation of histidine in most vertebrates also incorrectly labeled the METTL9 product as 1MH (PMID: 33563959 ). Similarly, a key paper that identified METTL18 as the enzyme responsible for tau-methylation of histidine incorrectly labelled the METTL18 product as 3MH (PMID: 33693809 ). Likewise, many members of the biochemical/nutrition community still incorrectly refer to 1MH as pi-methlyhistidine and 3MH as tau-methylhistidine. This has led to even more confusion. To maintain consistency for this compound description, all papers cited herein that incorrectly refer to 3MH as 1MH and vice versa, will have their conclusions re-stated and the citation will be marked with the phrase “3MH/1MH switch”. 3MH is a free amino acid arising from the proteolysis of 3MH-containing proteins and peptides. It is not synthesized on its own, nor can it be incorporated into proteins as an amino acid. However, it can be incorporated into certain dipeptides through the action of the enzyme known as carnosine synthase I. 3MH can only be generated from histidine residues through the action of methyltransferases as a protein post-translational modification event. Histidine methylation on the 3- or pi site of histidine-containing proteins is mediated by only one known enzyme – METTL9. Recent discoveries have shown that 3MH is produced in essentially all vertebrates via the methyltransferase enzyme known as METTL9 (3MH/1MH switch - PMID: 33563959 ). METTL9 is a broad-specificity S-adenosylmethionine-mediated methyltransferase that mediates the formation of the majority of 3MH present in mammalian and other vertebrate proteomes. METTL9-catalyzed methylation requires a His-x-His (HxH) motif, where 'x' is a small amino acid consisting of A, N, G, S, or T. This H[ANGST]H or HxH motif is found in a number of abundant mammalian proteins such as ARMC6, S100A9, and NDUFB3 (3MH/1MH switch - PMID: 33563959 ). In addition to these pi-His-methylated proteins, a specialized dipeptide called anserine (called beta-alanyl-3-methyl-L-histidine) that consists of beta-alanine and 3MH is also known and particularly well studied (PMID: 24137022 ). This methylated analog of carnosine, which is naturally produced in the liver via the enzyme carnosine synthase I (PMID: 20097752 ), is especially abundant in the skeletal muscles and brains of mammals, birds, and fish (PMID: 24137022 ). Anserine, like its homologs ophidine and carnosine, is believed to act as a pH buffer (for lactic acid generated by muscles), an antiglycating agent, and an antioxidant. Neither ophidine nor anserine are produced in humans, with humans being the only vertebrate not producing (or producing very little) methylated histidine versions of carnosine (PMID: 24137022 ). Because of its abundance in some muscle-related proteins but especially because of the high abundance of anserine found in poultry and fish, 3MH has been found to be a good biomarker for the consumption of meat (PMID: 21527577 ). Dietary studies have shown that general poultry consumption (p-trend = 0.0006) and especially chicken consumption (p-trend = 0.0003) are associated with increased levels of 3MH in human plasma (PMID: 30018457 ). The consumption of fish, especially salmon and cod, has also been shown to increase the levels of 3MH in serum and urine (3MH/1MH switch PMID: 31401679 ). As a general rule, urinary 3MH is associated with white meat intake (p< 0.001), whereas urinary 1MH is associated with red meat intake (p< 0.001) (3MH/1MH switch - PMID: 34091671 ).
Structure
Synonyms
ValueSource
(2S)-2-Amino-3-(1-methyl-1H-imidazol-5-yl)propanoic acidChEBI
3-Methyl-L-histidineChEBI
N-pros-Methyl-L-histidineChEBI
(2S)-2-Amino-3-(1-methyl-1H-imidazol-5-yl)propanoateGenerator
3-N-Methyl-L-histidineHMDB
L-3-MethylhistidineHMDB
N(pros)-Methyl-L-histidineHMDB
N3-Methyl-L-histidineHMDB
3-Methylhistidine hydrideHMDB
3-Methylhistidine dihydrochlorideHMDB
3-MethylhistidineChEBI
Pi methylhistidineHMDB
N(Pi)-methylhistidineHMDB
N Pi-methylhistidineHMDB
Molecular FormulaC7H11N3O2
Average Mass169.1811
Monoisotopic Mass169.085126611
IUPAC Name(2S)-2-amino-3-(1-methyl-1H-imidazol-5-yl)propanoic acid
Traditional Name3,methylhistidine
CAS Registry NumberNot Available
SMILES
[H][C@](N)(CC1=CN=CN1C)C(O)=O
InChI Identifier
InChI=1S/C7H11N3O2/c1-10-4-9-3-5(10)2-6(8)7(11)12/h3-4,6H,2,8H2,1H3,(H,11,12)/t6-/m0/s1
InChI KeyJDHILDINMRGULE-LURJTMIESA-N