60-18-4

Basic information

• Product Name: L-Tyrosine
• Synonyms: 3-(4-HYDROXYPHENYL)-L-ALANINE;2-Amino-3-(4-hydroxyphenyl)-propanoic acid;2-AMINO-3-(P-HYDROXYPHENYL)PROPIONIC ACID;4-HYDROXYPHENYLALANINE;FEMA 3736;H-L-TYR-OH;H-TYR-OH;L-3-[4-HYDROXYPHENYL]ALANINE
• CAS NO: 60-18-4
• Molecular Formula: C₉H₁₁NO₃
• Molecular Weight: 181.19
• EINECS: 200-460-4
• Product Categories: Inhibitors;Food and Feed Additive;Tyrosine [Tyr, Y];Amino Acids;Amino Acids and Derivatives;alpha-Amino Acids;Biochemistry;Nutritional Supplements;L-Amino Acids;Amino Acids;NORCURON;amino
• Mol File: 60-18-4.mol
• Article Data: 351

Chemical Properties

• Melting Point: >300 °C (dec.)(lit.)
• Boiling Point: 314.29°C (rough estimate)
• Flash Point: 176 °C
• Appearance: White to Pale-brown/powder
• Density: 1.34
• Refractive Index: -12 ° (C=5, 1mol/L HCl)
• Storage Temp.: Store at RT.
• Solubility: 1 M HCl: 25 mg/mL
• PKA: 2.2(at 25℃)
• Water Solubility: 0.45 g/L (25 ºC)
• Stability: Stable. Incompatible with strong oxidizing agents, strong reducing agents.
• Merck: 14,9839
• BRN: 392441
• CAS DataBase Reference: L-Tyrosine(CAS DataBase Reference)
• NIST Chemistry Reference: L-Tyrosine(60-18-4)
• EPA Substance Registry System: L-Tyrosine(60-18-4)

Safety Data

• Hazard Codes: Xi
• Statements: 36/37/38-40
• Safety Statements: 26-36-37/39-22
• WGK Germany: 3
• RTECS: YP2275600
• TSCA: Yes
• Hazardous Substances Data: 60-18-4(Hazardous Substances Data)

Usage

Chemical Description

L-Tyrosine is an amino acid, while the others are solvents, reagents, or reactants used in the synthesis of (–)-MY 336a.

Tyrosine

Tyrosine is an aromatic amino acid , can be found in a variety of proteins, and is particularly rich in casein milk protein, molecules containing phenol groups, Its structural formulais is as follows: Tyrosine is found by Li Biqi 1846 from casein, white crystalline powder, needle-like crystals or platelets from the water. The relative density of 1.456 (20 ℃), the isoelectric point of 5.66, UV absorption capacity, at a wavelength of 274nm of maximum light absorption, capable of reducing phosphomolybdic acid-phosphotungstic acid reagent (Folin reagent). Melting point: L-body decomposition 290~295 ℃ (slow heating), decomposition (rapid heating) 314~318 ℃, the racemate 290 to 295 decomposition (slow heating), decomposition (rapid heating) 340 ℃. Soluble in water, alcohol, acid and alkali, insoluble in ether. Dextrose solution reacts with tyrosinase to be red. laevo isomer friction can emit light , when at 170 ℃ heated with the barium hydroxide solution ,it can become a racemate, ortho of the phenolic hydroxyl group of tyrosine molecule is prone to chemical reaction, when coupled with a diazonium acid ,it is orange-red substance, when coupled with boiling dilute acetic acid and sodium nitrite ,it is purple or red, yellow when coupled with nitric acid, when in sulfuric acid reacting with titanium dioxide it is dark orange. L-tyrosine is a natural body, by proteolysis, refining. Tyrosine is a non-essential amino acid, is the material of a variety of body products, tyrosine is converted in vivo to a variety of biological substances by different metabolic pathways, such as dopamine, epinephrine, thyroxine, and melanin poppy (opium ) of papaverine. These substances and control neurotransmission and metabolism are closely related. Tyrosine Metabolism studies help to understand the pathogenesis of certain diseases. For example, urine black acid syndrome is related to tyrosine metabolic disorders, lack of urinary black acid oxidase in the patients causes tyrosine metabolite which is urine black acid can not continue to break down, when the air is discharged from the urine,it becomes black oxidation substance in the air. suffering from this disease, children's diapers exposed to air will gradually turn black, long home of urine also will be black. Albinism is also concerned with the metabolism of tyrosine, patients lacking tyrosinase makes tyrosine metabolites-3,4-dihydroxyphenylalanine impossible to form melanin so that the skin hairs are white.

non-essential amino acid

Amino acid is a derivative whose hydrogen atom of a hydrocarbon chain is substituted by amino. Amino acids are the basic structural units of proteins. Amino acids constituting natural proteins usually have 20 kinds. Except for proline, the amino acids are α-Amino acid. Its structural formula is: According to the polar nature of side chain R groups of α-amino acid , 20 common amino acids forming protein can be divided into four groups: (1) R group of non polar amino acids. (2) R groups having polarity but are not charged . (3) R group with a positively charged amino acid. (4) R groups are negatively charged amino acids. Tyrosine and serine, threonine, belong to the same R groups of polarity but do not have charged amino acids. In addition to glycine, all the α-amino acids,α-carbon atom is an asymmetric carbon atom and therefore optically active. The optically active amino acid symbol and its size depend on the nature of the R group, and the solution pH measured . 20 amino acids Involved in protein forming, tyrosine, phenylalanine and tryptophan have a light absorption capability, which is the base of using UV spectrophotometry (at a wavelength at 280nm) to measure protein concentration. The color reaction of the individual amino acid can be used for qualitative and quantitative analysis of these amino acids. Commonly used Mirren's reaction-when the phenol compound with Hg (NO3) 2 hot to make red, proteins containing tyrosine have this reaction; Pauly reaction-in alkaline solution, histidine and tyrosine acid conjugate with diazotized sulfonic acid to make red. Tyrosine is an polar aromatic amino acid that has phenolic hydroxyl group. Abbreviated as Tyr, Y. It and Tryptophan, lysine belong to ketogenic,glycogenetic and non-essential amino acids. In animals it is generated by hydroxylation of phenylalanine, both of them decompose and transform through the common pathways . It can be transformed into dopamine, epinephrine, norepinephrine, thyroxine, melanin, protopine and tyramine and other bioactive substances. Human and animal bodies’ congenital deficiency of phenylalanine hydroxylase, urine black acid oxidase, tyrosinase, can lead to phenylketonuria, black uric acid disease and albinism respectively . Tyrosine decomposition products are fumaric acid and acetoacetate. Above information from lookchem Andy. The above information is edited by the lookchem of Tian Ye.

Tyrosine in human metabolism

Tyrosine is an amino acid building blocks of proteins, and having a side chain having an aromatic ring of ionization, is addicted to the aqueous, tyrosine in the human and animal bodies is generated by the hydroxylation of phenylalanine, so when phenylalanine nutrition is adequate, it is non essential amino acid. Catabolism of tyrosine is firstly catalyzed by tyrosine aminotransferase in the liver , then transform into hydroxyphenyl pyruvate, the enzyme needs coenzyme pyridoxal phosphate . Hydroxyphenyl pyruvate by hydroxyl phenylketonuria hydroxylase role, while oxidative decarboxylation and metastasis, and the benzene ring ortho hydroxylation of the side chain of pyruvate to generate the urine black acid (glyoxylic acid). The enzyme is a protein containing copper metal, needing ascorbic acid and coenzyme consume molecular oxygen. Black acid in urine in the urine black acid dioxygenase (urine black acid oxidase) catalyzes the cleavage benzene to produce maleic acid acetoacetate; enzyme is a protein ferrous metals, the reactions require oxygen molecule to be involved in . Maleic acid via the corresponding acetoacetate isomerase role into fumarylacetoacetate need coenzyme glutathione. Finally, from the corresponding hydrolase hydrolyzed as fumaric acid and acetyl acid, so tyrosine is both glycogeneticr and ketogenic amino acids.

tyrosine kinase

tyrosine kinase , enzyme catalytic in peptide chain tyrosine residue (loci) phosphorylated,plays an important role in biological metabolism and cell communication, and molecular weight of 56,000, endometrial bound enzyme. The enzyme consists of two domains, a catalytic domain, accounting for most of the enzyme molecules, which contains two tyrosine phosphorylation sites and a C-terminal ; the other is the regulatory domain (i.e. SH2 domain), containing the N-terminal myristoylation, serine phosphorylation site and homologous regions. Tyrosine phosphorylation sites of the catalytic domain shows a great relation to tyrosine kinase activity , if these sites are phosphorylated, tyrosinekinase activity would be inhibited; on the contrary, if the phosphorylation of tyrosyl acid sites with phosphatase to dephosphorylate, the kinase activity can be significantly increased. Tyrosine phosphorylation sites near the ends of the C, but with different tyrosine kinase gene expression (e.g., c-src gene product family), the location of these sites is different, if it is missing out, it kinases is Activated. In addition, the polyomavirus middle T-antigen gene expression and c-src tyrosine kinase binding sites in the vicinity of 527 tyrosine at the site, since it is too close to this site , the formation of a steric hinders the phosphorylation site, it increases the kinase activity. SH2 domain in addition to homologous regions , other parts are of the large differences in structure, so it is possible to act with different regulating factors, plays a role in regulating the kinase activity.

Tyrosine iodide

Tyrosine iodide refers to an iodine compound that activated iodide replaces the three and five proton of benzene ring of tyrosine . Iodide process is mainly carried out on the thyroglobulin molecule acinar cavity near the top of the cell site. Tyrosine iodide and T4, T3 synthesis following steps: tyrosine firstly reacts with iodide generating a mono-iodotyrosine(MIT) and diiodo tyrosine (DIT) , two molecules of DIT are connected to generate T4. T3 is mainly in the surrounding tissue deiodination generated by the T4, but in the epithelial cells may also be generated by one molecule of MIT and DIT connection(see figure below): In epithelial cells, the above iodide reaction is carried out on the thyroglobulin molecule tyrosine residue, not in the presence of free tyrosine . Therefore, thyroid hormone synthesis is carried out in the thyroglobulin molecule. Thyroglobulin Is a glycoprotein , thyroglobulin in the human body is composed of four polypeptide , each polypeptide chain molecular weight 160 000, , there are two forms of the polymerization of four polypeptide chains: one is four polypeptide chain dicarboxylic mutual sulfur linkage; the other is in the first two disulfide linked polypeptide chains become dimers, which then covalently linked. Three-dimensional structural integrated tetramer of thyroglobulin molecule must be completed in order to make certain tyrosine residues have proper spatial position in order to iodide, and so as to make iodinated tyrosine combine into TH. Each molecule of thyroglobulin contains about 120 tyrosine residues , few tyrosine is iodinated . It is found that thyroglobulin molecules MIT and T3 relatively increase in rats, which may be a compensatory action to cope with iodine deficiency. Synthesis of T3 requires 1/4 iodine less than the synthesis of T4 , while the activity of T3 is greater than T4. Because the thyroglobulin molecule T4/T3 ratio of 12, and day T4, T3secretion rate ratio is 3,it is Visible that inside the thyroid T4 can be converted into T3. Reference: China Medical Encyclopedia Editing Committee; Zhang Changying editor of Chinese Medical Encyclopedia seventeen biochemistry.

Neuropeptide tyrosine

Neuropeptide tyrosine was a abiologically active polypeptide separated and purified in 1982 by the United States Tatemoto ,consisting of 36 amino acids, its structure are similar to pancreatic polypeptide, peptidesilk, it belongs to a family of peptides. Neuropeptide tyrosine genes consist of 7200 base pairs, contain four exons and five introns, can be transcribed, expressed neuropeptide tyrosine precursor containing 97 amino acids. It is mainly distributed in the central and peripheral nervous system, cardiovascular system, there is also rich in nerve fibers having a neuropeptide tyrosine. In the peripheral nervous system,it is mainly coexist with norepinephrine in sympathetic nervesand is released by the sympathetic nerve endings; in the cardiovascular system, neuropeptide tyrosine neurons are mainly in the atria, ventricles, and coronary sinus around; in the blood vessels, neuropeptide tyrosine aremainly in the arterial system, venous system are less distributed. Neuropeptide Tyrosine is one of the strong vasoconstrictor substance in the body , has a very strong and fast and lasting effect on coronary, femoral artery contraction cerebral artery, superior mesenteric artery, pulmonary artery and portal vein. Neuropeptide tyrosine is a regulatory matter, after intravenous injection can inhibit the effect of slow heart rate caused by the role of nervous excitement for a long time . Neuropeptide tyrosine mechanism is not yet understood, some people think it may be related to adenylate cyclase and G-protein activation; it is reported it has significantly depolarization on vascular smooth muscle cells. Neuropeptide tyrosine release may be associated with myocardial ischemia, cerebral vasospasm, the incidence of hypertension related. In 1989 Scott found that, after intraventricular injection,it not only did not increase blood pressure, but lower, it pointed out that such a role was the role of neuropeptide tyrosine in the brain stem, inhibiting sympathetic efferent impulses.

Melanin

Melanin Is a nitrogen-containing melanosomes , is especially distributed in skin, hair,the choroid layer, produced by the melanocytes. Tyrosine is a prerequisite for the synthesis of melanin, in tyrosinase ,firstly hydroxylate tyrosine into dopa (3,4 dihydroxyphenylalanine), following the dopa into dopa quinone. Tyrosinase is an enzyme that catalyzes the synthesis of melanin enzyme, is a copper-containing phenol oxidase. From dopa quinone reaction ,the following reactions are carried out automatically, mainly draw indole quinone through the side chains reaction, followed by aggregation, to synthesize melanin. Actually melanin must be combined with proteins and phospholipids to form a so-called melanin granules to exist. Pathogenesis of albinism is due to a congenital defect of tyrosinase, which makes melanocytes lose the ability to synthesize melanin.

Identification test

Take 0.1% of the sample solution 5ml, plus ninhydrin test solution (TS-250) 1ml , heat, reddish violet appears .

Content Analysis

Accurately weigh sample through the pre-drying after 105 ℃ 2h about 400mg, move into a 250mL flask, dissolve in about 50ml of acetic acid, add 2 drops of crystal violet test solution (TS-74), with 0.1mol/L perchloric acid, titrate to blue-green endpoint. At the same time carry out a blank test, and make the necessary corrections. 0.1mol/L perchloric acid equivalent L-tyrosine (C9H11NO3) 18.12mg per mL.

Toxicity

Safe for food (FDA, §172.320,2000).

Limited use

4.3% by weight of total protein foods (FDA, §172.320,2000). FEMA: bakery products, meat products, snack foods, condiments, seasoning flavoring products are 250mg/kg. The maximum amount permitted of food additives maximum allowable residue limits Chinese name of the food additive Chinese name of food allowed to use the food additive function of the additive permitted maximum amount (g/kg) maximum allowable residues (g/kg) L-Tyrosine food spices for food flavor preparation should not exceed the maximum allowable amount and the maximum allowable residues of each perfume ingredient in the GB 2760

Chemical Properties

Different sources of media describe the Chemical Properties of 60-18-4 differently. You can refer to the following data:
1. White needle crystal or crystalline powder, odorless, bitter taste, mp334 ℃ (decomposition) is insoluble in water (0.04%, 25 ℃), insoluble in ethanol, ether and acetone, soluble in dilute acid or base . The isoelectric point of 5.66.
2. White to off-white powder
3. L-Tyrosine is odorless and has a bland taste. L-Tyrosine is a nonessential amino acid, as it is synthesized in the human body from phenylalanine. It is a precursor to epinephrine, norepinephrine and dopamine, three important neurotransmitters.

Uses

Different sources of media describe the Uses of 60-18-4 differently. You can refer to the following data:
1. For biochemical research,it is used as amino acids nutritional in medicine for the treatment of polio, encephalitis, hyperthyroidism and other diseases. Nutritional supplements. for the manufacture of L-dopa diiodo tyrosine. After aminocarbonyl hot reaction with sugars, it can generate a special flavor substances. For tissue culture (L-tyrosine· 2Na· H2O), biochemical reagents, treatment of hyperthyroidism. Also available as modulation for rhe eldee, children's food and nutrition agents of plant leaves.
2. tyrosine is an amino acid. Cutaneous applications may produce an extra reserve of tyrosine in the skin, assisting or “activating” melanin synthesis. This in turn should increase and prolong the effect of the tanning process. Tyrosine’s effect is improved if the product contains vitamin B (riboflavin) plus an additional compound referred to chemically as ATP (adenosine triphosphate). experiments conducted with l-tyrosine in the form of watersoluble derivatives found that it penetrates the epidermis to the basal layer where the melanocytes are located. It is used in suntan accelerators and in skin-bronzing cosmetics to accelerate the tanning process.
3. L-Tyrosine is one of the 22 proteinogenic amino acids that are used by cells to synthesize proteins. L-Tyrosine is biologically converted from L-phenylalanine and is in turn is converted to L-DOPA and further converted into the neurotransmitters: dopamine, norepinephrine, and epinephrine.

Production Method

after precipitation of the casein, silk and other protein acid hydrolyzates,dissolve in dilute aqueous ammonia, with acetic acid neutralize to pH = 5, recrystallization to derive it. Extract The pig hydrolyzate to get second crude liquid crystalline pure cystine, store two days at 20 ℃, tyrosine precipitation, filtration, available tyrosine crude, refine also to receive L-Tyrosine . 1% Of pig yield. Casein as raw materials, reflux for several in hourshydrochloric acid , filter, and concentrate, soda and charcoal, crystallize,obtain products. Production of L-Tyrosine mainly takes proteolysis extraction. blood meal, hoof angle, silk and other raw materials, acid hydrolysis, separation and purification. Blood meal [HCl (hydrolysis)] → [110 ℃, 24h] hydrolyzate [rush acid] → [concentrated by evaporation] In addition to the acid [charcoal] → destaining solution [bleaching, cooling and crystallization] → L-Tyrosine crude [Activated Carbon (refined)] → [90 ℃, 30min] filtrate [crystalline] → L-tyrosine. Hydrolysis, rush acid the blood meal, water, industrial hydrochloric as 1: 1.3: 1 ratio by weight, respectively put into the hydrolyzed cylinder, heat to 112-114 ℃, stop after 24h of stirring under reflux , cool and filter to remove, give filtrate which is hydrolyzate . The hydrolyzate is concentrated by evaporation to a syrup, add water to dissolve ,oncentrated by evaporation, so repeat three times to rush the acid. Bleaching, crystallized concentrate is diluted with distilled water to the whole solution,add aqueous ammonia solution to pH 3.5, 1% charcoal is added, boiling with stirring 10min, stirring in a water bath at 90 ℃ incubated 30min, filter while hot, active carbon layer is washed with distilled water 3 times, and the filtrate and washings are combined. According to the Act, continue to use active carbon to make the solution pale yellow. The filtrate is placed in quiet place below 10 ℃ 24h, ie, crystalline precipitation, filtration to obtain crude L-tyrosine. Recrystallized tyrosine crude 1:20 distilled water is added, after the whole solution, plus 1% activated carbon, 90 ℃ insulation mixing 30min, filter hot and the filtrate cool to refined crystallize . The crystals are collected by filtration, washed with anhydrous ethanol twice, 60 ℃ drying, the finished product is L-tyrosine.

Occurrence

Reported found in white bread, macaroni, egg noodles, corn flakes, corn grits, oatmeal, wheat bran, wheat flakes, shredded wheat, barley brown rice, rye flour, whole grain wheat flour, buttermilk, blue cheese, cheddar cheese, cottage cheese, cream cheese, parmesan cheese, bacon, cured ham, frankfurters, pork sausage, canned red kidney beans, canned sweet corn, canned peas, canned lima beans, canned potatoes, almonds, cashews, peanuts, dates, beef, lamb, veal, chicken and turkey.

Definition

ChEBI: An optically active form of tyrosine having L-configuration.

Aroma threshold values

Detection: >10 ppm

Synthesis Reference(s)

Chemical and Pharmaceutical Bulletin, 28, p. 673, 1980 DOI: 10.1248/cpb.28.673Journal of the American Chemical Society, 100, p. 3559, 1978 DOI: 10.1021/ja00479a044Tetrahedron Letters, 29, p. 3591, 1988 DOI: 10.1016/0040-4039(88)85301-2

Biochem/physiol Actions

L-Tyrosine consists of a polar side chain and is a non-essential amino acid. It is utilized by cells to synthesize proteins that are involved in signal transduction. L-Tyrosine acts as a receiver of phosphate groups that are transferred by kinases.

Safety Profile

An experimental teratogen. Experimental reproductive effects. When heated to decomposition it emits acrid smoke and irritating fumes.

Purification Methods

Likely impurities are L-cysteine and the ammonium salt. L-Tyrosine is dissolved in dilute ammonia, then crystallised by adding dilute acetic acid to pH 5. Also, crystallise it from H2O or EtOH/H2O, and dry it at room temperature in a vacuum over P2O5. It sublimes at 235-240o/0.03mm with 99.2% recovery and unracemised [Gross & Gradsky J Am Chem Soc 77 1678 1955]. [Albert Biochem J 50 690 1952, Greenstein & Winitz The Chemistry of the Amino Acids J. Wiley, Vol 3 pp 2348-2366 1961, Beilstein 14 IV 2264.]

InChI:InChI=1/C9H11NO3/c10-8(9(12)13)5-6-1-3-7(11)4-2-6/h1-4,8,11H,5,10H2,(H,12,13)/t8-/m0/s1

Synthetic route

O-benzyl-N-tert-butoxycarbonyl-L-tyrosine (2130-96-3) → L-tyrosine (60-18-4)

Conditions	Yield
With trimethylsilyl trifluoromethanesulfonate; methyl-phenyl-thioether In trifluoroacetic acid at 0℃; for 0.5h;	100%
With trimethylsilyl trifluoromethanesulfonate; methyl-phenyl-thioether In trifluoroacetic acid at 0℃; for 0.5h; Product distribution; New peptide deprotection procedure: hard-soft acid-base concept; the role of soft bases (thioanisole, dimethylsulfide, diphenylsulfide) employed.;	100%
With dimethylsulfide; hydrogen fluoride at 0℃; for 2h; Product distribution; Var.: HF in anisole;	99.5%

L-Tyr-OMe (1080-06-4) → L-tyrosine (60-18-4)

Conditions	Yield
With ammonium bicarbonate; water In dichloromethane for 15h; α-chymotrypsin;	100%
at 25℃; for 0.833333h; enzyme alcalase from Bacillus licheniforms; pH 8.2;
With water at 37℃; Rate constant; pH 7.4; apparent rate constant of product formation; calculated nasal absorption rate constant;
With water; sodium chloride In dimethyl sulfoxide at 37℃; Rate constant; also human plasma as reagent;
Multi-step reaction with 4 steps 1: dichloromethane / 20 °C 2: copper diacetate; oxygen / acetonitrile / 20 h 3: potassium hydroxide / methanol; water / 7 h / Reflux 4: dimethyl sulfoxide; aq. phosphate buffer / 24 h / 37 °C / pH 7.4

L-tyrosine ethyl ester (949-67-7) → L-tyrosine (60-18-4)

Conditions	Yield
With ammonium bicarbonate; water In dichloromethane for 12h; α-chymotrypsin;	100%
With water at 37℃; Rate constant; pH 7.4; apparent rate constant of product formation; calculated nasal absorption rate constant;
With water; sodium chloride In dimethyl sulfoxide at 37℃; Rate constant; also human plasma as reagent;

N,O-bis-allyloxycarbonyl-L-tyrosine (104669-68-3) → L-tyrosine (60-18-4)

Conditions	Yield
With bis-triphenylphosphine-palladium(II) chloride; tri-n-butyl-tin hydride; acetic acid In dichloromethane Product distribution; slectivity of cleavge of allyl and allyloxycarbonyl groups; other amino acid derivatives;	100%
With tri-n-butyl-tin hydride; bis-triphenylphosphine-palladium(II) chloride In dichloromethane Ambient temperature;	95%

N-tert-butoxycarbonyl-O-2,6-dichlorobenzyl-L-tyrosine (40298-71-3) → L-tyrosine (60-18-4)

Conditions	Yield
With Nafion H; dimethylsulfide; 3-methyl-phenol; trifluoroacetic acid for 3h;	100%
With trimethylsilyl trifluoromethanesulfonate; methyl-phenyl-thioether In trifluoroacetic acid at 0℃; for 0.5h;	100%
With trimethylsilyl trifluoromethanesulfonate; methyl-phenyl-thioether In trifluoroacetic acid at 0℃; for 0.5h; Product distribution; New peptide deprotection procedure: hard-soft acid-base concept; the role of soft bases (thioanisole, dimethylsulfide, diphenylsulfide) employed.;	100%

Boc-Tyr-OH (3978-80-1) → L-tyrosine (60-18-4)

Conditions	Yield
With water at 170℃; for 0.05h; Microwave irradiation;	100%
With sodium tetrahydroborate In methanol; aq. phosphate buffer at 20℃; for 1h; Cooling with ice; Sealed tube;	87%
Multi-step reaction with 3 steps 1: potassium fluoride / N,N-dimethyl-formamide / 72 h / 20 °C 2: trifluoroacetic acid / dichloromethane / 24 h / 20 °C 3: acetonitrile / 2.6 h / pH 7.2 / Photolysis; HEPES buffer

4-Hydroxyphenylpyruvic acid (156-39-8) → L-tyrosine (60-18-4)

Conditions	Yield
With formate dehydrogenase; NAD; ammonium formate at 30℃; for 24h; PheDH;	99%
With L-phenylalanine; L-specific transaminase ywfG at 20℃; for 16h; pH=8; aq. potassium phosphate buffer; Enzymatic reaction;

4-hydroxyphenylpyruvate- (622-54-8) → L-tyrosine (60-18-4)

Conditions	Yield
With ammonium formate; tris hydrochloride; nicotinamide adenine dinucleotide; formate dehydrogenase; phenylalanine dehydrogenase In water at 30℃; for 24h;	99%
With L-glutamic acid; pyridoxal 5'-phosphate In water at 40℃; for 4h; E.coli Aspartate transaminase, pH 8;	80%

(RS)-tyrosinamide hydrochloride (117888-80-9) → L-tyrosine (60-18-4)

Conditions	Yield
With pyridoxal 5'-phosphate monohydrate; cobalt(II) chloride In aq. buffer at 40℃; for 6h; pH=7.0; Enzymatic reaction;	99%

(Z)-2-benzamido-3-(p-hydroxyphenyl)-2-propenic acid (64896-32-8) → L-tyrosine (60-18-4)

Conditions	Yield
With hydrogen; PF6 In tetrahydrofuran at 25℃; under 760 Torr;	98%
With hydrogen; PF6 In tetrahydrofuran at 25℃; under 760 Torr; effects of solvents dependency of the optical yields;

Nα-(allyloxycarbonyl)tyrosine O-allyl ether (104669-69-4) → L-tyrosine (60-18-4)

Conditions	Yield
With tri-n-butyl-tin hydride; bis-triphenylphosphine-palladium(II) chloride In dichloromethane Ambient temperature;	95%

D,L-Tyr-OPron (125511-37-7) → L-tyrosine (60-18-4)

Conditions	Yield
With Alcalase; pyridoxal 5'-phosphate; water In tert-butyl alcohol at 40℃; for 4h; pH=8.5; racemization of D-enantiomer; kin. resolution;	95%

benzyl tyrosinate (137838-07-4) → L-tyrosine (60-18-4)

Conditions	Yield
With Alcalase; pyridoxal 5'-phosphate; water In tert-butyl alcohol at 40℃; for 3h; pH=8.5; racemization of D-enantiomer; kin. resolution;	95%
With Alcalase; 3,5-dichlorobenzaldehyde In water; acetonitrile at 35℃; for 24h; pH=8.5; Enzymatic reaction; optical yield given as %ee;	95%

(S)-2-amino-3-(4-(propa-1,2-dien-1-yloxy)phenyl)propanoic acid → L-tyrosine (60-18-4)

Conditions	Yield
With tris[(3-sulfophenyl)phosphine]palladium(0) dodecasodium salt In aq. phosphate buffer; dimethyl sulfoxide at 37℃; for 0.0833333h; pH=7.8; Catalytic behavior; Reagent/catalyst;	95%

tyrosine ethyl ester (34081-17-9) → L-tyrosine (60-18-4)

Conditions	Yield
With Alcalase; 3,5-dichlorobenzaldehyde In water; acetonitrile at 35℃; for 72h; pH=7.5; Enzymatic reaction; optical yield given as %ee;	92%
With α-chymotrypsin In water; acetone at 30℃; for 24h; Product distribution; var. solvents; other amino acids;	50%

D,L-TyrO-iPr (81084-84-6) → L-tyrosine (60-18-4)

Conditions	Yield
With Alcalase; 3,5-dichlorobenzaldehyde In water; acetonitrile at 35℃; for 120h; pH=8.0; Enzymatic reaction; optical yield given as %ee;	92%

hexan-1-amine (111-26-2) + (S)-2-(3,5-Dinitro-4-oxo-4H-pyridin-1-yl)-3-(4-hydroxy-phenyl)-propionic acid (78641-67-5) → L-tyrosine (60-18-4) + 1-hexyl-3,5-dinitro-4-pyridone (74197-48-1)

Conditions	Yield
In pyridine Product distribution;	A 88.3% B n/a

tyrosine methyl ester hydrochloride (3417-91-2, 3728-20-9, 68697-61-0) → tyrosine (556-02-5) + D-tyrosine methyl ester (3410-66-0) + L-tyrosine (60-18-4)

Conditions	Yield
at 30℃; for 0.333333h; enzyme alcalase from Bacillus licheniforms; pH 8.0; Yields of byproduct given;	A n/a B 86% C n/a
at 30℃; for 0.333333h; enzyme alcalase from Bacillus licheniforms; pH 8.0; Yield given. Yields of byproduct given. Title compound not separated from byproducts;

p-borono-L-phenylalanine (76410-58-7) → L-tyrosine (60-18-4)

Conditions	Yield
With sodium L-ascorbate; fluorescein free acid In aq. phosphate buffer for 0.5h; pH=7.4; Irradiation;	85%

piruvate (57-60-3) + phenol (108-95-2) → L-tyrosine (60-18-4)

Conditions	Yield
With ethylenediaminetetraacetic acid; pyridoxal 5'-phosphate; Ammonium; recombinant wild-type thermophilic tyrosine phenol lyases from thermophilic microorganism Symbiobacterium toebii In aq. phosphate buffer at 37℃; pH=8; Green chemistry; Enzymatic reaction; stereoselective reaction;	84%
With ammonium chloride at 50℃; β-tyrosinase from Symbiobacterium thermophilum, 0.2 mM pyridoxal-5'-phosphate, 50 mM potassium phosphate buffer pH 8.0;

(S)-tert-butyl 2-((tert-butoxycarbonyl)amino)-3-(4-hydroxyphenyl)propanoate (18938-60-8) → L-tyrosine (60-18-4)

Conditions	Yield
With acetic acid In water at 160℃; for 0.0833333h; Microwave irradiation; optical yield given as %ee;	81%
Multi-step reaction with 3 steps 1.1: 1-ethyl-(3-(3-dimethylamino)propyl)-carbodiimide hydrochloride; dmap / dichloromethane / 0 - 21 °C / Inert atmosphere 2.1: trifluoroacetic acid / dichloromethane / 0 - 21 °C / Inert atmosphere 2.2: Inert atmosphere 3.1: water / 24 h / 21 °C / pH 7.5

L-serin (56-45-1) + phenol (108-95-2) → L-tyrosine (60-18-4)

Conditions	Yield
With ammonium acetate In water at 37℃; for 20h; pH 8.5; with Erwinia herbicola;	80%
at 70℃; for 2.5h; β-tyrosinase from Symbiobacterium thermophilum, 50 mM potassium phosphate buffer pH 8.0;

(S)-4-(4-hydroxybenzyl)-2,2-borabicyclo[3.3.1]nonane-1,3,2-oxazaborilidin-5-one → L-tyrosine (60-18-4)

Conditions	Yield
With hydrogenchloride In methanol; water at 20℃; for 0.5h; Inert atmosphere;	80%

methanol (67-56-1) + (S)-2-[(S)-2-Amino-3-(4-hydroxy-phenyl)-propionylamino]-3-(4-hydroxy-phenyl)-propionic acid (1050-28-8) → benzyl methyl ether (538-86-3) + L-tyrosine (60-18-4)

Conditions	Yield
With potassium hydroxide; [bis(acetoxy)iodo]benzene at 0 - 5℃; for 1.5h;	A 78% B n/a

Cbz-Tyr-OH (1164-16-5) → L-tyrosine (60-18-4)

Conditions	Yield
With boron trichloride In dichloromethane at 25℃; for 0.333333h;	72%
With cell extract of Sphingomonas paucimobilis SC 16113 In water at 42℃; for 20h; Enzymatic reaction;	100 % Chromat.
With ethylenediaminetetraacetic acid; phenylmethylsulphonyl fluoride; water In aq. phosphate buffer at 30℃; Kinetics; Reagent/catalyst; Microbiological reaction; Enzymatic reaction;

tyrosine methyl ester (1080-06-4, 3410-66-0, 18869-47-1) + Moz-Asp(Bzl)-OBzl (145126-13-2) → L-tyrosine (60-18-4) + Moz-Asp(Bzl)-D-Tyr-OMe

Conditions	Yield
Stage #1: tyrosine methyl ester With Alcalase; water In tert-butyl alcohol at 25℃; pH=8.5; kinetic resolution; Stage #2: Moz-Asp(Bzl)-OBzl With Alcalase In tert-butyl alcohol Condensation;	A n/a B 63%

D,L-tyrosine benzyl ester hydrochloride (15035-17-3, 87004-79-3) → L-tyrosine (60-18-4)

Conditions	Yield
Stage #1: D,L-tyrosine benzyl ester hydrochloride With lithium carbonate In water; tert-butyl alcohol at 23℃; for 0.166667h; Resolution of racemate; Stage #2: With 2-Hydroxymethylpyridine; Alcalase; water; zinc(II) acetate dihydrate In tert-butyl alcohol at 23℃; for 4h; Resolution of racemate; Enzymatic reaction; optical yield given as %ee;	63%

(S)-3-benzyloxycarbonyl-4-(4-hydroxyphenyl)methyloxazolidin-5-one (205866-50-8) → L-tyrosine (60-18-4)

Conditions	Yield
With boron trichloride In dichloromethane at 25℃; for 0.333333h;	62%

(2S)-2-amino-3-[4-(prop-2-ynyloxy)phenyl]-propionic acid → L-tyrosine (60-18-4)

Conditions	Yield
With tris[(3-sulfophenyl)phosphine]palladium(0) dodecasodium salt In aq. phosphate buffer; dimethyl sulfoxide at 37℃; for 0.0833333h; pH=7.8; Catalytic behavior; Reagent/catalyst;	47%

methanol (67-56-1) + L-tyrosine (60-18-4) → L-Tyr-OMe (1080-06-4)

Conditions	Yield
With thionyl chloride 1.) room temperature, 2 h, 2.) reflux, 0.5 h;	100%
With thionyl chloride	100%
With thionyl chloride at 0 - 20℃;	99%

ethanol (64-17-5) + L-tyrosine (60-18-4) → L-tyrosine ethyl ester (949-67-7)

Conditions	Yield
With hydrogenchloride	100%
With sulfuric acid at -10℃; Reflux;	90.2%
With amberlyst-15 Ambient temperature;	70%

ethyl trifluoroacetate, (383-63-1) + L-tyrosine (60-18-4) → N-trifluorosulfonyl-L-tyrosine (350-10-7)

Conditions	Yield
With triethylamine In methanol at 20℃; for 168h;	100%
With potassium methanolate In methanol at 40℃;	86%
With methanol; ion-exchange resin + form>; N,N,N',N'-tetramethylguanidine

L-tyrosine (60-18-4) + benzyl chloroformate (501-53-1) → Cbz-Tyr-OH (1164-16-5)

Conditions	Yield
With sodium hydroxide In tetrahydrofuran; water at 20℃; for 4h; Inert atmosphere; Cooling with ice;	100%
With N-ethyl-N,N-diisopropylamine	96%
With sodium hydroxide In tetrahydrofuran; water at 20℃; for 12h; Cooling with ice;	95%

methanol (67-56-1) + di-tert-butyl dicarbonate (24424-99-5) + L-tyrosine (60-18-4) → (S)-N-(tert-butoxycarbonyl)tyrosine methyl ester (4326-36-7)

Conditions	Yield
Stage #1: methanol; L-tyrosine With thionyl chloride for 3h; Inert atmosphere; Heating; Stage #2: di-tert-butyl dicarbonate With triethylamine In methanol for 20h; Inert atmosphere;	100%
Stage #1: methanol; L-tyrosine With thionyl chloride Heating; Stage #2: di-tert-butyl dicarbonate With sodium hydrogencarbonate In 1,4-dioxane; water at 20℃; Further stages.;

L-leucine (61-90-5) + L-phenylalanine (63-91-2) + L-tyrosine (60-18-4) + glycine (56-40-6) → H-Tyr-Gly-Gly-Phe-Leu-NH2 (60117-24-0)

Conditions

Yield

Stage #1: L-tyrosine With BF4(1-)*C7H13N3Pol(1+); benzotriazol-1-ol; O-(1H-benzotriazol-1-yl)-N,N,N',N'-tetramethyluronium hexafluorophosphate; N-ethyl-N,N-diisopropylamine In 1-methyl-pyrrolidin-2-one at 25℃; for 1h; Ionic liquid; Automated synthesizer; solid phase reaction; Stage #2: glycine In 1-methyl-pyrrolidin-2-one at 25℃; for 1h; Ionic liquid; Automated synthesizer; solid phase reaction; Stage #3: L-leucine; L-phenylalanine Further stages;

100%

dimethylallyl diphosphate (358-72-5) + L-tyrosine (60-18-4) → O-prenyl-L-tyrosine

Conditions	Yield
With tyrosine prenyltransferase SirD from Leptosphaeria maculans; calcium chloride In dimethyl sulfoxide; glycerol at 37℃; for 1.5h; pH=7.5; Reagent/catalyst; Enzymatic reaction;	100%
With 7-dimethylallyl tryptophan synthase from Aspergillus fumigatus; calcium chloride In dimethyl sulfoxide; glycerol at 37℃; for 16h; pH=7.5; Kinetics; Enzymatic reaction; stereoselective reaction;	36%
With potassium chloride; magnesium chloride In aq. buffer at 35℃; for 16h; pH=7.5; Kinetics;
With recombinant N-1‑dimethylallyltryptophan synthase from Fusarium f ujikuroi at 35℃; pH=7 - 9; Kinetics; Enzymatic reaction; regiospecific reaction;

L-tyrosine (60-18-4) + di(n-butyl)tin oxide (818-08-6) + 2-hydroxynaphthalene-1-carbaldehyde (708-06-5) → (S,E)-6,6-dibutyl-3-(4-hydroxybenzyl)naphtho[1,2-h][1,3,6,2]dioxazastannonin-4(3H)-one

Conditions	Yield
In methanol at 120℃; for 0.25h; Microwave irradiation;	99.28%

dichlorotricarbonylruthenium(II) dimer + L-tyrosine (60-18-4) → tricarbonylchloro(tyrosinato)ruthenium(II)

Conditions	Yield
With sodium methylate In methanol at 20℃; for 24h; Inert atmosphere; Schlenk technique; Darkness;	99.2%

L-tyrosine (60-18-4) → tyrosamine (51-67-2)

Conditions	Yield
With pyridoxal 5'-phosphate; aromatic L-amino acid decarboxylase In various solvent(s) at 30℃; for 48h;	99%
at 300 - 340℃;
Bestrahlen der Kristalle mit Roentgen-Strahlen;

L-tyrosine (60-18-4) + methyl chloroformate (79-22-1) → (S)-3-(4-hydroxyphenyl)-2-[(methoxycarbonyl)amino] propionic acid (338386-45-1)

Conditions	Yield
With sodium hydrogencarbonate In tetrahydrofuran; water at 20℃;	99%
With sodium hydroxide In water at 5℃; for 1.5h; Schotten-Baumann reaction;	90%
With sodium hydrogencarbonate In tetrahydrofuran; water at 20℃;	80%
With sodium hydroxide In 1,4-dioxane; water at 0 - 20℃;

L-tyrosine (60-18-4) → 4-((3H-diazirin-3-yl)methyl)phenol

Conditions	Yield
With [bis(acetoxy)iodo]benzene; ammonia In methanol at 0 - 20℃; for 2h; Inert atmosphere;	99%

L-tyrosine (60-18-4) + acetyl chloride (75-36-5) → (S)-3-(3-acetyl-4-hydroxyphenyl)-2-aminopropanoic acid hydrochloride (32404-28-7)

Conditions	Yield
With aluminium trichloride In nitrobenzene at 100℃; for 6h;	98%
Stage #1: L-tyrosine With aluminum (III) chloride In nitrobenzene at 20℃; for 0.166667h; Stage #2: acetyl chloride In nitrobenzene at 100℃; for 6h;	83%
With aluminium trichloride In nitrobenzene at 100℃; Friedel-Crafts acetylation;	80%

methanol (67-56-1) + isobutyraldehyde (78-84-2) → (S)-3-(4-Hydroxy-phenyl)-2-(2-methyl-1-methylcarbamoyl-propylamino)-propionic acid methyl ester

Conditions	Yield
at -30 - 20℃;	98%

Upstream product

• 2280-44-6 D-Glucose 
• 57-60-3 piruvate 
• 108-95-2 phenol 
• 125511-37-7 D,L-Tyr-OPron 
• 137838-07-4 benzyl tyrosinate 
• 81084-84-6 D,L-TyrO-iPr 
• 1164-16-5 Z-L-Tyr-OH 
• 4357-95-3 L-tyrosine β-naphthylamide 
• 162536-44-9 methyl 2-amino-3-(3-hydroxyphenyl)propionate 
• 1080-06-4 tyrosine methyl ester 
• 145126-13-2 Moz-Asp(Bzl)-OBzl 
• 484-42-4 angiotensin I 
• 111296-11-8 N-norvalyl-tyrosine 

Downstream Products

• 14942-15-5 N-pyridoxyl-L-tyrosine 
• 537-55-3 N-acetyl-L-tyrosine 
• 17355-23-6 N-acetyl-O-acetyl-L-tyrosine 
• 28047-05-4 (S)-N-acetyl-p-methoxyphenylalanine 
• 2901-77-1 N-acetyltyrosine 
• 30697-69-9 ethyl N-acetyl-tyrosinate 
• 35436-78-3 ON-diacetyltyrosine 
• 412335-18-3 4-(2-acetamido-3-oxobutyl)phenyl acetate 
• 556-02-5 ?Tyr 
• 1080-06-4 tyrosine methyl ester 
• 1080-06-4 L-Tyr-OMe 
• 3415-08-5 L-tyrosine N-carboxyanhydride 
• 10488-32-1 N-(2-cyano-ethyl)-L-tyrosine 
• 537-49-5 N-methyl-L-tyrosine 

Relevant articles and documents

Squamins C–F, four cyclopeptides from the seeds of Annona globiflora

Four cyclic octapeptides, squamins C–F, were isolated from the seeds of Annona globiflora Schltdl. These compounds share part of their amino acid sequence, -Pro-Met(O)-Tyr-Gly-Thr-, with previously reported squamins A and B. Their structures were determined using NMR spectroscopic techniques together with quantum mechanical calculations (QM-NMR), ESI-HRMS data and a modified version of Marfey's chromatographic method. All compounds showed cytotoxic activity against DU-145 (human prostate cancer) and HeLa (human cervical carcinoma) cell lines. Clearly, A. globiflora is an important source of bioactive molecules, which could promote the sustainable exploitation of this undervalued specie.

Biochemical characterization of a recombinant acid phosphatase from Acinetobacter baumannii

Genomic sequence analysis of Acinetobacter baumannii revealed the presence of a putative Acid Phosphatase (AcpA; EC 3.1.3.2). A plasmid construct was made, and recombinant protein (rAcpA) was expressed in E. coli. PAGE analysis (carried out under denaturing/ reducing conditions) of nickel-affinity purified protein revealed the presence of a nearhomogeneous band of approximately 37 kDa. The identity of the 37 kDa species was verified as rAcpA by proteomic analysis with a molecular mass of 34.6 kDa from the deduced sequence. The dependence of substrate hydrolysis on pH was broad with an optimum observed at 6.0. Kinetic analysis revealed relatively high affinity for PNPP (Km = 90 μM) with Vmax, kcat, and Kcat/Km values of 19.2 pmoles s-1, 4.80 s-1(calculated on the basis of 37 kDa), and 5.30 × 104 M-1s-1, respectively. Sensitivity to a variety of reagents, i.e., detergents, reducing, and chelating agents as well as classic acid phosphatase inhibitors was examined in addition to assessment of hydrolysis of a number of phosphorylated compounds. Removal of phosphate from different phosphorylated compounds is supportive of broad, i.e., 'nonspecific' substrate specificity; although, the enzyme appears to prefer phosphotyrosine and/or peptides containing phosphotyrosine in comparison to serine and threonine. Examination of the primary sequence indicated the absence of signature sequences characteristic of Type A, B, and C nonspecific bacterial acid phosphatases.

Powerful Steroid-Based Chiral Selector for High-Throughput Enantiomeric Separation of α-Amino Acids Utilizing Ion Mobility-Mass Spectrometry

Stereospecific recognition of amino acids (AAs) plays a crucial role in chiral biomarker-based diagnosis and prognosis. Separation of AA enantiomers is a long and tedious task due to the requirement of AA derivatization prior to the chromatographic or electrophoretic steps which are also time-consuming. Here, a mass-tagged chiral selector named [d0]/[d5]-estradiol-3-benzoate-17β-chloroformate ([d0]/[d5]-17β-EBC) with high reactivity and good enantiomeric resolution in regard to AAs was developed. After a quick and easy chemical derivatization step of AAs using 17β-EBC as the single chiral selector before ion mobility-mass spectrometry analysis, good enantiomer separation was achieved for 19 chiral proteinogenic AAs in a single analytical run (～2 s). A linear calibration curve of enantiomeric excess was also established using [d0]/[d5]-17β-EBC. It was demonstrated to be capable of determining enantiomeric ratios down to 0.5% in the nanomolar range. 17β-EBC was successfully applied to investigate the absolute configuration of AAs among peptide drugs and detect trace levels of-AAs in complex biological samples. These results indicated that [d0]/[d5]-17β-EBC may contribute to entail a valuable step forward in peptide drug quality control and discovering chiral disease biomarkers.