Arabinose synthesis

Synthesis from i-arabinose Synthesis of l,4-dideoxy-l,4-imino-L-arabinitol (2) from methyl 3-L-arabinopyranoside has been reported (Scheme 4). The double inversion involving the introduction of the azide function at CA has been effected in... 

The reaction is used for the chain extension of aldoses in the synthesis of new or unusual sugars In this case the starting material l arabinose is an abundant natural product and possesses the correct configurations at its three chirality centers for elaboration to the relatively rare l enantiomers of glucose and mannose After cyanohydrin formation the cyano groups are converted to aldehyde functions by hydrogenation m aqueous solution Under these conditions —C=N is reduced to —CH=NH and hydrolyzes rapidly to —CH=0 Use of a poisoned palladium on barium sulfate catalyst prevents further reduction to the alditols... 

A second approach for the synthesis of 6-formylpterin (23) involves the condensation of triamin opyrimidinone (10) with 5-deoxy-L-arabinose (26). The key diol is obtained in four steps starting from compound (10). Cleavage of the diol side chain is achieved either with periodate (39) or with lead(TV) (40) to furnish 6-formylpterin (23) in 45% overall yield. 

Replacement of heterocyclic rings in nucleosides by ring systems which do not occur in nature represents another approach to compounds which may have activity against viral and neoplastic diseases. One of the early successes in this category involves replacement of a pyrimidine ring by a triazine. The synthesis starts with a now classical glycosidation of a heterocycle as its silylated derivative (146) with a protected halosugar (145), in this case a derivative of arabinose... 

Fischer s original method for conversion of the nitrile into an aldehyde involved hydrolysis to a carboxylic acid, ring closure to a cyclic ester (lactone), and subsequent reduction. A modern improvement is to reduce the nitrile over a palladium catalyst, yielding an imine intermediate that is hydrolyzed to an aldehyde. Note that the cyanohydrin is formed as a mixture of stereoisomers at the new chirality center, so two new aldoses, differing only in their stereochemistry at C2, Tesult from Kiliani-Fischer synthesis. Chain extension of D-arabinose, for example, yields a mixture of D-glucose and o-mannose. 

Arabinose, configuration of. 982 Kiliani-Fischer synthesis on. 995 Arachidic acid, structure of, 1062 Arachidonic acid, eicosanoids from, 1069-1070... 

The related 3-deoxy-D-waHnooctulosonic acid aldolase (KDO aldolase F.C 4.1.2.23) likewise suffers from an unattractive equilibrium constant but allows a simple synthesis of specifically labelled KDO from D-arabinose and labelled pyruvate28. 

Deoxy-sugars. Part II. Synthesis of 2-Deoxy-D-ribose and 3-Deoxy-D-xylose from D-Arabinose, P. W. Kent, M. Stacey, and L. F. Wiggins,/. Chem. Soc., (1949) 1232-1235. 

With the same synthetic sequence, labeled ribose molecules produced AIRs labeled on the ribose moiety. From D-erythrose and (l3C)NaCN, the Fischer-Kiliani synthesis, as modernized by Serianni et al.59 produced D-(l-l3C)ribose and D-(l-l3C)arabinose. The labeled arabinose was transformed into D-(2-l3C)ri-bose in the presence of dioxobis(2,4-pentanedionato)-0-0 -molybdenum(VI) in... 

Deoxy-3-fluoro-D-glucose (25%) and -mannose (40%) were prepared from 2-deoxy-2-fluoro-D-arabinose by a chain-extension reaction (cyanohydrin synthesis). Likewise, 4-deoxy-4-fluoro-D-glucose ° (27%) and -mannose (45%) were prepared from 3-deoxy-3-fluoro-D-arabinose. ... 

A strategy has been described for the synthesis of 2-ethyIthio-6-(3-hydroxy-1,2-0-isopropylidenepropyl)pteridin-4(3//)-one 90 which can be used as a useful intermediate for the conversion of neopterin to biopterin. Diaminopyrimidinone 86 reacts with D-arabinose phenylhydrazone 87, the obtained diastereomeric mixture 88 is converted into its isopropylidene derivative 89 which under oxidation conditions yields 90 <00H(53)1551>. 

The asymmetric synthesis of / -branched carboxylic acid derivatives was accomplished by conjugate addition of mixed organoaluminum reagents to optically active Arabinose-derived c -unsaturated A-acyloxazolidinones (Scheme 47). Efficient stereocontrol was achieved using different optically active bicyclic oxazolidinones, yielding (.R)- or ( -configured / -branched carboxylic acid derivatives.136a... 

Digressing from reductive desulfurization into stereochemistry, we may use this experimental proof of the equivalent symmetry of D-mannitol as a basis for an independent proof of the configurations of D-mannitol and D-arabitol. The reduction of D-arabinose yields the optically active pentitol, D-arabitol application of the Sowden-Fischer synthesis to D-arabinose yields D-mannose86 which upon reduction gives D-mannitol. 

Following the synthesis by Comforth and his associates18 of NeuAc from oxalacetate and 2-acetamido-2-deoxy-D-mannose, Ghalambor and Heath29,31 prepared KDO (isolated as the crystalline methyl 2,4,5,7,8-penta-0-acetyl-3-deoxy-D-manno-2-octulopyranosonate, 70) from D-arabinose and oxalacetate by an analogous reaction (see Scheme 20). 

The procedure that Kuhn and Baschang99 had reported for the synthesis of NeuAc was extended by Hershberger and Binkley100 to a synthesis of KDO, as follows. Condensation of di-ter -butyl oxalacetate (85 see Scheme 25) with D-arabinose gave the epimeric mixture of lactone esters, 86 and 87, which was separated by fractional recrystallization. When 86 was heated in aqueous solution, the enol lactone, 88, was produced from 87, an enol lactone diastereomeric with 88 was obtained under these conditions. Compound 88 was converted into ammonium KDO by treatment with aqueous ammonia. 

These circumstances became apparent to the authors when they attempted to study the formation of KDO 8-phosphate as catalyzed by purified bacterial extracts. These extracts did not catalyze the formation of KDO 8-phosphate from D-ribose 5-phosphate, but required D-arabinose 5-phosphate as the substrate Heath and Ghalambor29 showed that the KDO 8-phosphate synthetase reaction, observed in Pseudomonas extracts by Levin and Racker, is also catalyzed by extracts from Escherichia coli strains 0 111 B4 and J-5. Rick and Osborn136 showed that the KDO 8-phosphate synthetase from a Salmonella typhimurium mutant conditionally defective in cell-wall synthesis had a KM of 6 mM as compared to a KM of 170 pM for the enzyme from wild-type cells. 

D-Ribono-1,4-lactone (1) readily condenses with acetone, under acidic catalysis with mineral acids or anhydrous copper sulfate, to give 2,3-0-isopropylidene-D-ribono-1,4-lactone (16a), which was employed for the synthesis of 5-deoxy and 5-0-substituted derivatives of D-ribono- 1,4-lactone and D-ribitol (24). Acid removal of the 1,3-dioxolane protecting group gave products having probable inhibitory activity of arabinose 5-phosphate isomerase (25). Other applications of 16a for the synthesis of natural products will be discussed later. 

Aldono-1,5-lactones and free aldonic acids react with alcohols in the presence of hydrogen chloride to give the corresponding alkyl aldonates (84). The reaction is slower with 1,4-lactones. Because esterification takes place very slowly in the absence of an acidic catalyst, aldonic acids and their lactones may be recrystallized from boiling alcohols without appreciable esterification (85). However, in some instances, alkyl esters are formed under these conditions. For example, essentially pure ethyl L-mannonate was isolated (6.4% yield) from the mother liquors of crystallization L-man-nono-1,4-lactone, obtained by Kiliani synthesis from L-arabinose (86). Similarly, repeated recrystallization from ethanol of crude 2,3,4,6-tetra-O-acetyl-D-glucono- 1,5-lactone afforded the corresponding ethyl gluconate derivative (87). 

The cyanohydrin synthesis of higher sugars, which involves intermediate aldonolactones, allows the introduction of a 14C label in the sugar chain. Thus, for example, L-[5-l4C]arabinose was synthesized (12) from D-xylose, which was first converted, by addition of K14CN and hydrolysis, into D-[ 1-... 

The two most important natural pentoses, 1 -arabinose and 1 -xylose, occur in nature as polymeric anhydrides, the so-called pentosans, viz. araban, the chief constituent of many vegetable gums (cherry gum, gum arabic, bran gum), and xylan, in wood. From these pentapolyoses there are produced by hydrolysis first the simple pentoses which are then converted by sufficiently strong acids into furfural. This aldehyde is thus also produced as a by-product in the saccharification of wood (cellulose) by dilute acids. Furfural, being a tertiary aldehyde, is very similar to benzaldehyde, and like the latter undergoes the acyloin reaction (furoin) and takes part in the Perkin synthesis. It also resembles benzaldehyde in its reaction with ammonia (p. 215). 

---