DE1151794B - Process for the preparation of the monosodium salt of phospho-enolpyruvic acid - Google Patents

Description

Process for the preparation of the monosodium salt of phospho-enolpyruvic acid The invention relates to a process for the preparation of the monosodium salt of phosphoenolpyruvic acid.

The important phospho-enolpyruvic acid was produced so far in the form of the silver barium salt from pyruvic acid (see reports der Deutschenchemischen Gesellschaft, Vol. 68, 1935, p. 597, and Vol. 69, 1936, p.2331; Journal of biological Chemistry, Vol. 149, 1943, p. 369 and Vol. 190, 1951, p. 21; Helvetica Chimica Acta, Vol. 39, 1956, p. 1461), or from chlorolactic acid and phosphorus oxychloride (see E. 0. Ball, Biochemical Preparations, Vol. 2, 1952, p. 25). In any case Large amounts of inorganic salts have to be removed and they are time-consuming and lossy Carry out precipitation reactions. In addition, the yields are the same as above mentioned procedure with 2 to a maximum of 7010 and experience shows that can only be achieved after some practice (cf.

S. P. Colowick and N. 0. Kaplan, Methods in Enzymology, Vol. 1957, P. 223). The method of the invention now makes it possible for many biochemicals Purposes required phospho-enolpyruvic acid to produce much cheaper.

Furthermore, a process is known by which the ethyl bromopyruvate is converted with triethyl phosphite according to the Perkow reaction into the triethyl phospho-enolpyruvate according to the following formula (see Chemical Reports, Vol. 91, 1958, p. 704) If one further intends to hydrolytically split off the alcohol residue from the phosphoenolpyruvic acid ester, the phospho-enol bond is also split, so that it is impossible to produce the free phospho-enolpyruvic acid from the ester by the Perkow reaction in this way.

It has now been found that one can also use the Perkow reaction the free, i.e. the non-esterified halopyruvic acid.

The invention therefore relates to a method for producing the Monosodium salt of phosphoenolpyruvic acid, according to which one is halopyruvic acid with tribenzyl phosphite according to Perkow. The resulting phosphoenolpyruvic acid dibenzyl ester becomes split off the two benzyl groups in a non-hydrolytic manner.

The implementation takes place in the first stage according to the following formula: The dibenzyl ester of phospho-enolpyruvic acid obtained in the first stage is, as a free acid, much easier to separate and purify than the corresponding ester, because it is neutralized in the reaction mixture with alkaline agents such as sodium hydrogen carbonate and the free acid is acidified from the sodium salt can deposit.

The reaction of the halopyruvic acid is preferably carried out in the presence made of a solvent; compounds are used as solvents, which do not form esters with this acid, e.g. B. hydroxyl-free compounds, such as Ether.

The reaction is carried out at a temperature below 40 "C, e.g. between 0 and 15 "C.

The bromine compound is particularly used as halopyruvic acid.

The non-hydrolytic cleavage is carried out in such a way that one first a benzyl group by reacting the dibenzyl ester with sodium iodide in one splitting off organic solvent and then from the resulting monosodium salt desphosphoenolpyruvic acid monobenzyl ester the second benzyl group by hydrogenation splits off with hydrogen.

The first benzyl radical is preferably split off with sodium iodide in methyl ethyl ketone, while the hydrogenating cleavage of the second benzyl radical with hydrogen in the presence of palladium, which is applied to carbon, in aqueous Methanol executes.

The splitting off of the benzyl residues from the dibenzyl ester of phospho-enolpyruvic acid proceeds according to the following formula: Acidification creates the free acid from the sodium salt.

It has been found that the selective hydrogenative cleavage of the Benzyl radical because of the double bond present in the molecule of the type of used Solvent depends. In a mixture of methanol and water in proportion 1: 1, the preferred solvent, the rates of the hydrogenating Cleavage of the benzyl group and hydrogenation of the double bond of the sodium salt of the monobenzyl ester of phospho-enolpyruvic acid about as 20: 1, so that after the absorption of 1 mol of hydrogen phospho-enolpyruvic acid without formation the phospholactic acid can be easily separated. Curiously, cautious the speeds in pure methanol are much less favorable, namely how 4: 1.

You can also use the two benzyl radicals from the dibenzyl ester of phospho-enolpyruvic acid split off directly by hydrogenation; but in this case it turns out to be necessary to purify the initially formed free acid via the barium and silver salt, losing the advantage of working in organic solvents.

The two-stage spin-off process is therefore sizeable because of its Advantages applied preferentially. The phospho-enolpyruvic acid serves as an intermediate product for the manufacture of remedies.

Example In a 2 liter flask flushed with nitrogen 370 g of dimethylaniline were added to 330 g of benzyl alcohol with stirring. After the further Additions of 300 cc of anhydrous ether were made at 0 to 5 "C within 2 hours 136 g of phosphorus trichloride in 100 cc of ether were added dropwise to the mixture. After further 30 minutes for room temperature became the dimethylaniline hydrochloride by the addition of 200 ccm of ether precipitated and quickly filtered off with the greatest possible exclusion of moisture. This Salt was washed three times with 50ccm ether each time, the ethereal solutions became Stored for 10 hours at 20 "C, and the ether was removed from the further precipitate poured off.

After evaporation of the ether, the residue was at 1.0 mm mercury pressure heated to 100 ° C (bath temperature), whereby 41 g of the residue distilled off. There remained 321 g, that is 91.20 / 0 yield of crude tribenzyl phosphite, in the flask return.

86.5 g of 830% tribenzyl phosphite were cooled to 10 ° C. and 33.6 g of bromopyruvic acid were added dropwise to 30 cc of ether with further cooling.

The mixture was then stirred for a further 30 minutes at room temperature and pour the reaction solution into a separatory funnel, in which 150 ccm of water, 18 g of sodium hydrogen carbonate and pieces of ice. After the termination the evolution of carbon dioxide ether was added to the separating funnel, the resulting separated aqueous layer and shaken it out again with 30 ccm of ether; the Ether layers were discarded. The aqueous layer was cooled to 0 ° C, in 50 ccm of ether poured over a separatory funnel and slowly with a frozen one Mixture of 25 cc concentrated hydrochloric acid and 50 cc water added. The secluded Oil was immediately taken up in ether, the aqueous acidic layer with it twice more 25 ccm each, and the combined ethereal solutions were over sodium sulfate dried. After the ether solution had been concentrated in vacuo, the residue was left 10 Stand at-150 ° C. for hours, then the deposited crystals were filtered off. Upon further concentration of the solution, an additional amount of crystals was obtained; the yield was 42 g, that is 60010 of theory, the melting point amounts to 75 to 78 3 C. At room temperature, the dibenzyl ester decomposed after a long period of time Time.

C17Hli06 P; Molecular weight 348.

Calculated . . C 58.67, H 4.92, P 8.90; found ... C 56.66, H 5.37, P8.74.

To 34.8 g of the dibenzyl ester of phospho-enolpyruvic acid were with complete exclusion of moisture, 15 g of sodium iodide in 120 cc of methyl ethyl ketone given. After 3 hours, the deposited salt was filtered off with suction at room temperature.

This was then slurried in 100 cc of methyl ethyl ketone, again sucked off and this measure repeated again. The now pale yellow salt became kept at room temperature under high vacuum at 0.1 mm mercury column until it was bone dry. The yield was 21 g, that is 77010 of theory. Of the Monobenzyl ester was dissolved in 250 to 300 cc of methanol and the solution in vacuo concentrated until the salt began to precipitate. The first precipitate became the methanol Poured off, the methanolic solution cooled to O'C and the sodium salt of the monobenzyl ester precipitated in crystalline form by the gradual addition of ether; the yield was 18 g, that's 640/0 of theory.

CloH1oOoPNa; Molecular weight 280.

Calculated . . C 42.80, H 3.60, P 11.07; found ... C 42.09, H 4.31, P 11.28.

1.4g of the monosodium salt of the monobenzyl ester of phospho-enolpyruvic acid were in 30 ccm of a mixture of methanol and water in a ratio of 1: 1 according to the Addition of 2 spatula tips of 50% palladium-carbon at room temperature with hydrogen treated. After 25 minutes the theoretical amount of hydrogen, 112 cc, had been consumed.

The solution was filtered and evaporated to dryness in vacuo at 20 ° C. The remaining glassy salt, 1 g. was dissolved in 40 cc of methanol, the insoluble filtered off and the residue washed with 20 ccm of methanol; the cleaned methanolic solutions were evaporated to 30ccm. By slowly adding them of twice the volume of ether to the concentrated solution Ice cooling and stirring the monosodium salt of phospho-enolpyruvic acid was deposited in crystalline form; it was dried over phosphorus pentoxide at 20 ° C. The yield was 0.6 g are 58% of theory.

C3H406PNa 1 H2O; Molecular weight 208.

Calculated ... C 17.30, H 2.91, P 14.90; found ... C 17.38, H 4.02, P 14.94.

Claims (2)

PATENT CLAIMS: 1. Process for the preparation of the monosodium salt of phospho-enolpyruvic acid, characterized in that halopyruvic acid with tribenzyl phosphite according to Perkow at a temperature below 40 "C, e.g. between 0 and 15 "C, converts, from the resulting phospho-enolpyruvic acid dibenzyl ester first a benzyl group with sodium iodide in an organic solvent, especially in methyl ethyl ketone, split off and from the resulting monosodium salt of the phosphoenolpyruvic acid monobenzyl ester the second benzyl group by hydrogenation splitting off with hydrogen in the presence of a solvent or that both benzyl radicals removed from the dibenzyl ester by hydrogenation with hydrogen. 2. The method according to claim 1, characterized in that the second benzyl radical from the monobenzyl ester by hydrogenation with hydrogen in the presence of palladium-carbon in a mixture of methanol and water in a ratio of 1: 1 split off. Documents considered: British Patent No. 786 322; U.S. Patent No. 2,685,552; The natural sciences, vol. 39, 1952, P. 353; Chemical Reports, Vol. 87, 1954, pp. 755 to 758; Vol. 88, 1955, pp. 662 bis 665; Vol. 91, 1958. pp. 704 to 712; Journal of the American Chemical Society, Vol. 77, 1955, pp. 2871-2875.