Glycine dimethyl

All the amino-acids of physiological importance are a-amino-acids, e.g. (in addition to the above compounds), alanine or a-amino-propionk acid, CHaCH(NH,)COOH, and leucine or a-amino-Y-dimethyl-rt-butyric acid, (CH,)aCHCH,CH(NHa)COOH, and naturally occurring samples (except glycine) are therefore optically active. 

The influence of a large number of oc-amino acids on the values of and k at have been determined. These a-amino acids included glycine, L-valine, L-leucine, L-phenylalanine, L-tyrosine, L-tryptophan, NOrmethyl-L-tryptophan (L-abrine), N-methyl-L-tyrosine, N,N-dimethyl-L-tyrosine and p -me thoxy-N-me thyl -L -phenyl al anine. 

Most pteridines are degraded to pyrazines and when they do yield pyrimidines, these may well be the ones from which they were made. However, some useful preparations of pyrimidines from pteridines are known. Thus, reduction of pteridin-7(8//)-one (732) and subsequent hydrolysis yields N-(4-aminopyrimidin-5-yl)glycine (733) (52JCS1620) and hydrolysis of 5,8-dimethylpteridine-6,7(5Ff,8Ff)-dione (734) gives dimethyl-... 

Glycine ethyl ester hydrochloride, 14, 46 16, 86 17, 92 Grignard reaction in -butyl ether, 11, 84 with acetaldehyde, 12, 48 with butyl p-toluenesulfonate, 10, 4 with carbon dioxide, 11, 80 with dimethyl sulfate, 11, 66 with ethyl carbonate, 11, 98... 

Ytterbium, trinitratotris(dimethyl sulfoxide)-structure, 1, 97 Ytterbium, tris(acetylacetone)(4-ammo-3-penten-stereochemistry, 1,81 Ytterbium complexes acetylacetone, 2,373 dipositive oxidation state hydrated ions, 3,1109 polypyrazolylborates, 2,255 Ytterbium(III) complexes ethyl glycinate, diacetate... 

In a less straightforward way, D-glucose (393) underwent a Maillard-type reaction with an excess of glycine (394) under microwave irradiation to afford 5-hydroxy-l,3-dimethyl-2(l/f)-quinoxahnone (395) as a major product, Repetition with labeled reactants suggested that the product contained six carbon atoms from the sugar and four from the amino acid on this evidence, a detailed mechanism has been postulated. 

GME glycine methyl ester GDM glutamic dimethyl ester EDA ethylendiamine GAM glucosamine HDA hexadecylamine BSA bovine serum albumin OVA ovalbumin CA carbonic anhydrase MYO myoglobin H alkaline hydrolysis for converting ester groups from GME or GDM into free carboxylic acid groups that were subsequently activated with EDC for further modifications. 

Fig. 4 Absorption spectra of the green type GFP chromophore as a function of pH. (a) Absorption spectra of model compound FIBDI (4-hydroxybenzy lidene-1,2-dimethyl-imidazolinone) in aqueous solution cationic (- 1 M HC1), neutral acetate buffer, pH 5.5), and anionic 1 M NaOFI). Reproduced with permission from [71]. (b) Absorption spectra of AvGFP as a function of pH pH 5.46 (a), pH 8.08 (b), pH 10.22 (c), pH 11.07 (d), pH 11.55 (e), pH 13.0 (f), pH 1.0 (g). For curves (a-e) the buffer contained 0.01 M each sodium citrate, sodium phosphate and glycine. Sample f was in 0.1 M NaOH, and sample g was in 0.1 M HC1. Reproduced with permission from [6],...

Partly saturated pyrazino[l,2-r-]pyrimidines were prepared by formation of the pyrazine ring. 2-Substituted-8-hydroxy-3,4-dihydro-177,277-pyrazino[l,2-r-]pyrimidin-l-ones were prepared by a [6+0] synthesis involving cyclization of 6-hydroxy-pyrimidine-4-(fV-hydroxyethyl)carboxamides <2005W02005/087766>. The 2/7-pyra-zino[l,2-c]pyrimidine-3-carboxamide 164 (Y = NH) was formed from [5+1] atom fragments via the uracil derivative 163 (Y = NH) and DMF-dimethyl acetal. Compounds 163 were prepared from 6-chloromethyluracil and glycine methyl ester 162 (Y = NH) (Scheme 20) <2004W02004/014354>. 

Glutaronitrile, 3-hydroxy-, 46, 48 Glycerol chlorohydrin, 46, 24 Glycine (-butyl ester, 45, 47 conversion to acetamidoacetone, 45,1 Glyoxal, phenyl-, 48,109 Glyoxals from esters and the potassium salt of dimethyl sulfoxide, 48, 112... 

Alkyl dimethyl glycinates, 24 148 Alkyl diphenyl phosphates, 11 494 Alkyl dithiocarbazate esters, 13 568 Alkyleneamine, pK values, 8 487t Alkylenediamines, 8 485 Alkylene terephthalate polymers, 20 32 Alkyl ether phosphates, 24 146 Alkyl ethers, 10 574, 575 uses for, 10 580-581 Alkyl fumarates, 15 491... 

The mechanism of transmethylation was then examined. A series of deuterium-labeled methylated compounds were synthesized by du Vigneaud s group, including arsenocholine, trimethylamine, dimethyl-glycine, and dimethylthetin. Of these only betaine and dimethylthetin served as methyl donors. In 1949 Dubnoff found that choline could only act as a donor under aerobic conditions, when it was oxidized to betaine. 

Care must be taken in the choice of organic solvent. Chloroform should never be used under the basic conditions due to the risk of the formation of isocyanides (see Chapter 7) and the use of carbon disulphide can lead to formation of dithiocarba-mates, e.g. dimethyl A -(ethoxycarbonylmethyl)iminodithiocarbonate is formed (35-39%), as the major product in high purity, in the liquiddiquid two-phase methyl-ation of ethyl glycinate in carbon disulphide [15]. The product is useful as an intermediate in the synthesis of thiazoles [15] and dihydrooxazoles [16]. 

Chan and co-workers (73) generated the novel mtinchnone-sydnone hybrids 127-128 by cyclodehydration of the sydnone glycine (125) and alanine (126), respectively. Trapping with DMAD gave 129 and 130. Maleic anhydride and dimethyl maleate failed to capture these mtinchnone-sydnone hybrids. Exposure of 125 to trifluoroacetic anhydride gave acylated mtinchnone 131 [by nuclear magnetic resonance (NMR)]. Workup afforded the hydrolysis product 132 (Scheme 10.24). 

Instead of alanine and valine, several other chiral auxiliaries have been used, such as tert-leucine13, leucine14 and isoleucine15. In some cases diastereomeric excesses may be higher with the dihydropyrazines 5 and 6, derived from 0,0-dimethyl-alkylation with 3-bromo-propyne gives a de of 60% with (2S)-2,5-dihydro-2-isopropyl-3,6-dimethoxypyrazine (3), in contrast to 85% de with 516 and >95% de with 613. 

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