Phosphorylation hydroxy compounds

The classical route to chloropyrazines is by treatment of a hydroxy-pyrazine with phosphoryl chloride bromopyrazines are similarly prepared by using phosphoryl bromide, phosphorus tribromide, or a mixture of both. Thus, treatment of hydro xypyrazine with phosphoryl chloride gives chloropyrazine in 92% yield,147 and treatment of the hydroxy compound with a mixture of phosphoryl bromide and phosphorus tribromide gives bromopyrazine in 58% yield.266 The use of phosphorus pentahalides frequently leads to substitution products (Scheme 22) for example, when hydroxypyrazine is treated with a mixture of phosphoryl bromide and phosphorus pentabromide both monobromo- and 2,6-dibromopyrazines are formed.287,268 Bromina-tion of hydroxypyrazine with bromine in the presence of small... 

Chloro-3-methylpyrazine (101,535) and 2-chloro-5-phenylpyrazine (363, 365a, 377, 824, 825) have been prepared from the corresponding hydroxy compound and phosphoryl chloride, 2-chloro-6-methylpyrazine from 2-hydroxy-6-methylpyrazine and phosphoryl chloride with one drop of dimethylformamide (681), and 2-benzyl(or s-butyl, isobutyl, or isopropyl)-3phosphoryl chloride with a trace of concentrated sulfuric acid (80). 2-Chloro-6-methyl-3-propyl- (826), 3[Pg.99]

Dichloropyrazines have also been prepared from the corresponding hydroxy compounds as follows 2,3-dihydroxypyrazine with phosphoryl chloride containing pyridine (481, 757) [see Schneller and May (828) re the use of phenylphosphonic dichloride at 150-170°] 2,3-dihydroxypyrazine and its methyl, dimethyl, phenyl, diphenyl, and 5-methy 1-6-phenyl derivatives with phosphoryl chloride (483, 829) [N.B. error in work of Minovici and Bente (830)] 2-chloro-5-hydroxypyrazine with phosphoryl chloride (831) 2-chloro-6-hydroxypyrazine with phosphoryl chloride at reflux for 6hours (832) and 2,5-dihydroxy-3-phenylpyrazine and3,5-dihydroxy-2-phenylpyrazine with phosphoryl chloride at 180-200° (829). 

Many derivatives of carboxy chloropyrazines have been prepared by the action of phosphoryl chloride on the corresponding hydroxypyrazine. In this way were prepared 2-chloro-3-methoxycarbonylpyrazine (371, 423, 836), 2-chloro-3-methoxycarbonyl-5,6-diphenylpyrazine (but the corresponding hydroxy compound did not react with phosphorus tribromide) (837), and 3-chloro-2-methoxycarbonyl-... 

In phosphorylation, A hydroxy compound is phosphorylated by reaction with 1 mole of dibromomalonamide and 2 moles of triethylphosphite. Thus the reagent was added in portions to a mixture of triethylphosphite and excess n-propyl alcohol as solvent. Malonamide promptly separated and, after standing for a time, was... 

Synthesis of Phosphoric Acids and their Derivatives. - Among various approaches to phosphate esters the phosphorylation of phenols with dialkyl cyanophosphonate and the synthesis of triaryl phosphates under phase-transfer conditions are worthy of mention. Mixed trialkyl phosphates are also reported to be formed by brief cathodic electrolysis of the reaction of dialkyl phosphonates with aromatic aldehydes and ketones, presumably by rearrangement of the initial a-hydroxy compounds. Further reports have appeared of the generation of metaphosphates by various methods. The synthesis of analogues 1 of famesyl pyrophosphate which incorporate photoactive esters has been reported both compounds are competitive inhibitors of farnesyl transferase. 

The most common substitution reaction on hydroxy-substituted pyridazino[4.5-c/]pyridazines is the substitution by chlorine atoms. This is achieved by reaction of the hydroxy compound with phosphoryl chloride, a mixture of phosphoryl chloride and phosphorus pentachloride, or a mixture of phosphoryl chloride and pyridine at elevated temperatures. In most cases, yields are only moderate. 

If the starting co-hydroxyalkylphosphonate is obtained via the Abramov reaction, presenting a convenient route to a-hydroxyalkylphosphonates, the final heterocycles formed in the one-pot process may possess additional functionality such as a hydroxy (compound 70, Scheme 39) [85] or phosphoryl group (compound 71, Scheme 40) [86], In the latter case, the starting carbonyl compounds of rather complex structure gave rise to directional synthesis of biologically active compounds 72 and 73. 

Trichloro bromomelhane Phosphorylation of hydroxy compounds and amines... 

Without additional reagents w.ax. Boronic and halogenohoronic acid esters B,0-Heterocyclics s. 16, 156 Bisboric acid esters s. 16, 157 Diacoxystannanes from stannanes > SnHg > Sn(OAc)2 s. 17,689 Phosphorylation of hydroxy compounds OH OPO3H2 Simplified procedure—Labeled compounds s. 17, 164 Dithiophosphoric acid esters -e- via dithiophosphoric acid 0,0-diesters—P-Lebeled compounds s. 17, 165 ... 

The hydroxamic acid function in most alicyclic and aromatic compounds is stable to hot dilute acid or alkali, and derivatives cannot undergo normal base-catalyzed Lessen rearrangement. Di Maio and Tardella," however, have shown that some alicyclic hydroxamic acids when treated with polyphosphoric acid (PPA) at 176°-195° undergo loss of CO, CO.2, or H2O, in a series of reactions which must involve earlj fission of the N—0 bond, presumably in a phosphoryl-ated intermediate. Thus, l-hydroxy-2- piperidone(108) gave carbon monoxide, 1-pyrroline (119), and the lactams (120 and 121). The saturated lactam is believed to be derived from disproportionation of the unsaturated lactam. 

As summarized in Figure 27.7, the mevalonate pathway begins with the conversion of acetate to acetyl CoA, followed by Claisen condensation to yield acetoacety) CoA. A second carbonyl condensation reaction with a third molecule of acetyl CoA, this one an aldol-like process, then yields the six-carbon compound 3-hydroxy-3-methylglutaryl CoA, which is reduced to give mevalonate. Phosphorylation, followed by loss of C02 and phosphate ion, completes the process. 

Chiral phosphoryl and sulfinyl groups are known as efficient auxiliaries in asymmetric synthesis. As reported below, their asymmetric induction in the a-posi-tion has been used to prepare chiral non-racemic organophosphorus compounds a-substituted by a sulfur function. Such compounds can also be obtained from their a-hydroxy analogues by OH-4 SR stereoselective transformation. 

However, the most common and important method of synthesis of chiral non-racemic hydroxy phosphoryl compounds has been the resolution of racemic substrates via a hydrolytic enzyme-promoted acylation of the hydroxy group or hydrolysis of the 0-acyl derivatives, both carried out under kinetic resolution conditions. The first attempts date from the early 1990s and have since been followed by a number of papers describing the use of a variety of enzymes and various types of organophosphorus substrates, differing both by the substituents at phosphorus and by the kind of hydroxy (acetoxy)-containing side chain. 

The first P-chiral hydroxy phosphoryl compounds that were enzymatically resolved into enantiomers were o-hydroxyaryl phosphines and their oxides 75. The resolution was achieved via enzyme-assisted hydrolysis of their O-acetyl derivatives 74, the most effective enzymes being CE and Upase from C. rugosa (CRL) (Equation 35). The highest enanfioselectivity was observed in the case of naphthyl derivatives (Equation 36), having a P=0 moiety. ... 

The phosphoramidic chloride (11) has been employed to phosphorylate phenols and alcohols, including carbohydrates.16 Other activity in phosphorylation chemistry has been mostly concentrated in two main areas. In the first of these, Japanese workers have continued their studies on the use of 2-substituted-4-nitrophenyl-phosphoric acids. The 7V-protonated form of the 2-dimethylamino-compound (12 R = Me) is a better phosphorylating agent than the corresponding 2-diethylamino-compound. The reaction of (12) with hydroxy-amines results in selective O-phos-... 

The regiospecificity of the exclusive O-acylation [8] and O-phosphorylation [9] of P-dicarbonyl compounds (Chapter 3) also illustrates the effect of phase-transfer catalysts on the stereochemical course of reactions. Similarly, directed reduction of P-hydroxy ketones using tetramethylammonium trisacetoxyborohydride leads to the preferential formation of the anti dihydroxy system in high yield with a stereoselectivity >95% [10] (Section 11.4). 

Substances that interfere with the formation of polyprenyl phosphates are of 3 types (1) those that interfere with the biosynthesis of polyprenyl diphosphate for example, inhibitors of 3-hydroxy-3-meth-ylglutaryl-coenzyme A reductase (HMG-CoA reductase), (2) compounds that prevent the recycling of polyprenyl diphosphate (bacitracin), and (3) compounds that prevent the phosphorylation of... 

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