Threonine mixtures

The L-threonine (EC 4.1.2.5), D-threonine (EC 4.1.2.-) or L-allothreonine aldolases (EC 4.1.2.6 synonymous to S1IMT) can be used for resolution of racemic (allo)threonine mixtures by highly selective cleavage of the unwanted isomers42, but can also efficiently direct the anabolic pathways. The substrate spectrum includes propanal, butanal and dodecanal43. 

In the optical resolution of DL-threonine mixtures by batch preferential crystallization, changes of solution concentration and crystal purity were measured. The mechanism of nucleation of the un-seeded enantiomer was discussed to explain the purity decrease of the resolved crystals. From the observation of crystallization behavior of the seed crystals of L-threonine, it was concluded that the existence of the D-enantiomer on the surface of the seed caused the sudden nucleation when they grew to attain sufficient amounts. 

Crystallization Method. Such methods as mechanical separation, preferential crystallisation, and substitution crystallisation procedures are included in this category. The preferential crystallisation method is the most popular. The general procedure is to inoculate a saturated solution of the racemic mixture with a seed of the desired enantiomer. Resolutions by this method have been reported for histidine (43), glutamic acid (44), DOPA (45), threonine (46), A/-acetyl phenylalanine (47), and others. In the case of glutamic acid, the method had been used for industrial manufacture (48). 

Phospho-L-threonine (L-threonine-O-phosphate) [1114-81-4] M 199.1, m 194 (dec), [a]p -7.37 (c 2.8, H2O) (pK as above). Dissolve in the minimum volume of H2O, add charcoal, stir for a few min, filter and apply onto a Dowex 50W (H" " form) then elute with 2N HCI. Evaporate the eluates under reduced pressure whereby the desired fraction produced crystals of the phosphate which can be recrystd from H2O-MeOH mixtures and the crystals are then dried in vacuo over P2O5 at 80 . [de Verdier Acta Chem Scand 7 196 7955.]... 

For this class of reactions, only a few examples which proceed with reasonable diastereoselectivity are known. Allylation of a-methoxycarbamate 1, easily obtained as a 1 1 mixture of isomers by anodic oxidation of protected threonine, produces an 83 17 mixture of enantiomers on treatment with trimethyl(2-propcnyl)silanel03. Cyanation with trimcthylsilyl cyanide proceeds less stereoselectively (67 33 93 % yield). 

Chiral tricyclic fused pyrrolidines 29a-c and piperidines 29d-g have been synthesized starting from L-serine, L-threonine, and L-cysteine taking advantage of the INOC strategy (Scheme 4) [19]. L-Serine (23 a) and L-threonine (23 b) were protected as stable oxazolidin-2-ones 24a and 24b, respectively. Analogously, L-cysteine 23 c was converted to thiazolidin-2-one 24 c. Subsequent N-allylation or homoallylation, DIBALH reduction, and oximation afforded the ene-oximes, 27a-g. Conversion of ene-oximes 27a-g to the desired key intermediates, nitrile oxides 28 a-g, provided the isoxazolines 29 a-g. While fused pyrrolidines 29a-c were formed in poor yield (due to dimerization of nitrile oxides) and with moderate stereoselectivity (as a mixture of cis (major) and trans (minor) isomers), corresponding piperidines 29d-g were formed in good yield and excellent stereoselectivity (as exclusively trans isomers, see Table 3). 

The Helferich-Wedemeyer procedure may give mixtures of the anomers, depending on the nature of the aglycon. For example, condensation of bromide 128 with N-(benzyloxycarbonyl)-L-threonine penta-chlorophenyl ester (171) gave both N-(benzyloxycarbonyl)-3-0-(2,3,4,6-tetra-O-acetyl-a- and -/J-D-glucopyranosyl)-L-threonine pen-tachlorophenyl ester135 (172 and 173, respectively), but only the fi-D... 

Differently from serine, ESI-MS analysis of homoserine (HSer) solutions reveals an unusually abundant diprotonated homoserine octamers [(HSer)g-2H], but not the expected monoprotonated [(HSer)g H]" one." A 3/1 mixture of L-serine and L-homoserine yields abundant mixed serine octamers with the incorporation of one or two homoserine molecules into the cluster. CID of the isolated [(Ser)6(HSer)2-H] cluster leads to the preferentially loss of two neutral serine molecules. Homoserine is always retained. The ESl-MS spectral patterns of threonine and allothreonine solutions is similar to that of homoserine. A 1/1 mixture of D-serine and D-threonine yields abundant mixed singly- and doubly-charged octamers incorporating from 2 to 6 threonine molecules. Their relative abundance indicates that threonine may incorporate freely into serine clusters because the additional methyl group does not interfere with the bonding of the cluster. 

The first reaction is p-elimination in cysteine, serine, phosphoserine, and threonine residues due to attack by hydroxide ion, leading to the formation of very reactive dehydroalanine (DHA). In a cystine residue, this results in rupturing of the disulfide bond and liberation of a sulfide ion and free sulfur (Figure 13.4). Nucleophilic additions of the s-amino group of the protein-bound lysine to the double bond of DHA residue causes crosslinking of the polypeptide chain. After hydrolysis, a mixture of L-lysino-L-alanine and L-lysino-D-alanine, with probably a small proportion of dl and dd isomers,... 

Carp, Cyprinuscarpio, are attracted to cysteine, asparagine, glutamic acid, threonine, and alanine. Extracts from Tubifexworms contain at least 17 amino acids. Of these, binary mixtures of one non-polar amino acid and one polar uncharged amino acid attracted carp most and led them to explore the area. Alanine, valine, and glycine proved to be the simplest combination to release significant attraction and exploration (Saglio etal, 1990). 

Cod Gains morhua Lugworm, Arenicola Mixture threonine. Pawson, 1977... 

Batch crystallizers, applications, 102 Batch preferential crystallization, purity decrease of L-threonine crystals in optical resolution, 251-259 Bayer proce description, 329 Benzene, hi -pressure crystallization from benzene-cydohexane mixture, 281-289... 

Alkaline hydrolysis with barium, sodium, or lithium hydroxides (0.2-4 M) at 110°C for 18-70 h126-291 requires special reaction vessels and handling. Reaction mixtures are neutralized after hydrolysis and barium ions have to be removed by precipitation as their carbonate or sulfate salts prior to analysis which leads to loss of hydrolysate. Correspondingly, peptide contents are difficult to perform by this procedure. Preferred conditions for alkaline hydrolysis are 4M LiOH at 145 °C for 4-8 h where >95% of tryptophan is recovered 291 An additional inconvenience of the alkaline hydrolysis procedure is the dilution effect in the neutralization step and thus the difficult application to the analyzer if micro-scale analysis is to be performed. The main advantage is the good recovery of tryptophan and of acid-labile amino acid derivatives such as tyrosine-0-sulfate1261 (Section 6.6) as well as partial recovery of phosphoamino acids, particularly of threonine- and tyrosine-O-phosphate (Section 6.5). 

Nevertheless, rearrangements can be suppressed, in most cases, when dediazoniation is performed in hydrogen fluoride/pyridine (48 52 w/w) mixture,308,310 since this less acidic medium stabilizes carbocations (such as the phenonium cation) to a far lesser extent and provides more nucleophilic fluoride anions which, however, cannot totally match the anchimeric assistance of the aryl or hydroxy group in tyrosine (5g) and threonine (5h). 

To Fmoc 0-glycosyl threonine (erf-butyl ester 20 (290 mg, 0.4 mmol) dissolved in dry dichloromethane (5 mL) is added dry trifluoroacetic acid (3 mL) at 0°C. The mixture is allowed to warm to room temperature, and the reaction is monitored by TLC (dichloro-methane-ethanol 10 1). After 3 h, the conversion is complete. The solvent is evaporated in vacuo. Toluene (10 mL) is codistilled in vacuo from the remainder. Small amounts of an unpolar impurity are separated by flash chromatography on silica gel (20 g) in dichloro-methane-ethanol (15 1) yield 230 mg (90%) [a]D 69.7° (c 1, CHC13) Rf 0.32 (CH -ethanol 10 1). 

---