Enzymatic synthesis of deoxyribonucleosides

Abstract

The present invention relates to a method for the in vitro synthesis of deoxyribonucleosides and enzymes suitable for this method.

Description

RELATED APPLICATIONS

This application is a divisional application of U.S. Ser. No. 10/049,750 filed Dec. 9, 2002, incorporated herein by reference in its entirety, which is a §371 of PCT/EP00/08088 filed Aug. 18, 2000, which claims priority from European Patent Application No. 99 116 425.2 filed Aug. 20, 1999.

DESCRIPTION

The present invention relates to a method for the in vitro enzymatic synthesis of deoxyribonucleosides and enzymes suitable for this method.

Natural deoxyribonucleosides (deoxyadenosine, dA; deoxyguanosine, dG; deoxycytidine, dC and thymidine, dT) are building blocks of DNA. The N-glycosidic bond between nucleobase and sugar involves the N₁ of a pyrimidine or the N₉ of a purine ring and the C₁, of deoxyribose.

In the living cells the four deoxyribonucleosides (dN) result from the “salvage pathway” of nucleotide metabolism. A group of enzymes is involved in cellular catabolism of deoxyribonucleosides. Besides deoxyriboaldolase (EC 4.1.2.4) and deoxyribomutase (EC 5.4.2.7), this group also includes thymidine phosphorylase (EC 2.4.2.4) and purine nucleoside phosphorylase (EC 2.4.2.1). These four enzymes are induced by the addition of deoxyribonucleosides to the growth medium. The genes coding for these enzymes have been shown to map closely together on the bacterial chromosome (Hammer-Jesperson and Munch-Peterson, Eur. J. Biochem. 1 7 (1970), 397 and literature cited therein). In E. coli the genes as described above are located on the deo operon which exhibits an unusual and complicated pattern of regulation (Valentin-Hansen et al., EMBO J. 1 (1982), 317).

Using the enzymes of the deo operon for synthesis of deoxynucleosides was described by C. F. Barbas III (Overproduction and Utilization of Enzymes in Synthetic Organic Chemistry, Ph.D. Thesis (1989), Texas A&M University). He applied phosphopentomutase and thymidine phosphorylase for the synthesis of deoxynucleosides. Deoxyribose 5-phosphate was prepared by chemical synthesis (Barbas III et al., J. Am. Chem. Soc. 112 (1990), 2013-2014), which makes this compound expensive as starting material and not suitable for large scale synthesis. He also made deoxyriboaldolase available as a recombinant enzyme and investigated its synthetic applicability but neither he nor C. H. Wong (Microbial Aldolases in Carbohydrate Synthesis: ACS Symp. Ser. No. 466: Enzymes in Carbohydrate Synthesis, Eds. M. D. Bednarski, E. S. Simon (1991), 23-27) were able to carry out a coupled one-pot synthesis employing all three enzymes. It appears likely that some drawbacks exist which could not be circumvented. Among these drawbacks are insufficient chemical equilibrium, instability of intermediates, such as deoxyribose 1-phosphate and inactivation and inhibition effects of involved compounds on the enzymes.

Evidence of an advantageous equilibrium is given by S. Roy et al. (JACS 108 (1986), 1675-78). For the aldolase reaction the equilibrium is on the desired product side (deoxyribose 5-phosphate), for the phosphopentomutase it is on the wrong side (also deoxyribose 5-phosphate) and for the purine nucleoside phosphorylase it is on the desired synthesis product side. The authors suggest coupling of the three enzyme reactions to obtain reasonable yields. Contrary to these suggestions they prepared deuterated deoxyguanosine and thymidine in a two step procedure, that is deoxyribose 5-phosphate in a first step and deoxynucleoside in a second step. Isolated yields of the second step were 11% and 5% for deoxyguanosine and thymidine, respectively. These low yields are also obtained in the preparation of arabinose-based nucleosides (Barbas III (1990), supra). These low yields indicate serious drawbacks for the use of the enzymes of the deo operon in a synthetic route which have to work in the reverse direction of their biological function, which is degradation of deoxynucleosides.

Thus, there does not exist any economical commercial method at present for the enzymatic in vitro synthesis of deoxyribonucleosides. Hitherto, for commercial purposes, deoxynucleosides are generated from fish sperm by enzymatic cleavage of DNA. This method, however, involves several disadvantages, particularly regarding difficulties of obtaining the starting material in sufficient quantity and quality.

Therefore, it was an object of the invention to provide a method, by means of which the drawbacks of the prior are eliminated at least partially and which allows efficient and economical synthesis of deoxyribonucleosides without any dependence on unreliable natural sources.

Surprisingly, it was found that the drawbacks of previous enzymatic synthesis routes can be avoided and deoxyribonucleosides can be obtained in high yields of e.g. at least 80% based on the amount of starting material.

In a first aspect, the present invention relates to a method for the in vitro enzymatic synthesis of deoxyribonucleosides comprising reacting deoxyribose 1-phosphate (dR1P) and a nucleobase, wherein a deoxyribonucleoside and inorganic phosphate are formed.

The reaction is catalyzed by an enzyme which is capable of transferring a deoxyribose moiety to a nucleobase, with a deoxyribonucleoside being formed. Preferably, the reaction is catalyzed by a thymidine phosphorylase (TP, EC 2.4.2.4) or a purine nucleoside phosphorylase (PNP, EC 2.4.2.1). For the EC designation of these enzymes and other enzymes mentioned below reference is made to the standard volume Enzyme Nomenclature 1992, Ed. E. C. Webb, Academic Press, Inc.

These enzymes and other enzymes mentioned below are obtainable as native proteins from natural sources, i.e. any suitable organisms selected from eukaryotes, prokaryotes and archaea including thermophilic organisms. Further, these enzymes are obtainable as recombinant proteins from any suitable host cell which is transformed or transfected with a DNA encoding said enzyme. The host cell may be a eukaryotic cell, a prokaryotic cell or an archaea cell. Particular preferred sources of native or recombinant TP or PNP are prokaryotic organisms such as E. coli. Recombinant TP may be isolated from E. coli strain pHSP 282 (CNCM I-21 86) deposited on Apr. 23, 1999, which is a recombinant E. coli strain transformed with a plasmid containing the E. coli deoA (thymidine phosphorylase) insert. Recombinant PNP may be isolated from E. coli strain pHSP 283 (CNCM 1-2187) deposited on Apr. 23, 1999, which is a recombinant E. coli strain transformed with a plasmid containing the E. coli deoD (purine nucleoside phosphorylase) insert. The nucleotide sequence of the TP gene and the corresponding amino acid sequence are shown in SEQ ID NO.1 and 2. The nucleotide sequence of the PNP gene and the corresponding amino acid sequence are shown in SEQ ID NO.15 and 16 and 3 and 4.

The nucleobase, to which the deoxyribose unit is transferred, will be selected from any suitable nucleobase. For example, the nucleobase may be a naturally occurring nucleobase such as thymine, uracil, adenine, guanine or hypoxanthine. It should be noted, however, that also non-naturally occurring analogs thereof are suitable as enzyme substrates such as 2-thio-uracil, 6-aza-uracil, 5-carboxy-2-thiouracil, 6-aza-thymine, 6-aza-2-thio-thymine and 2,6-diamino-purine.

Preferably the inorganic phosphate is removed from the reaction. This removal is preferably effected by (i) conversion to inorganic pyrophosphate, (ii) precipitation/complexation and/or (iii) substrate phosphorylation.

Conversion to inorganic pyrophosphate may be effected by a phosphate transfer from a phosphorylated, preferably polyphosphorylated substrate such as fructose diphosphate (FDP), wherein a phosphate group is cleaved from the phosphorylated substrate and reacts with the inorganic phosphate, with inorganic pyrophosphate (PPi) being formed. This phosphate transfer is preferably catalyzed by a PPi-dependent phosphorylase/kinase, e.g. by a PPi-dependent phosphofructokinase (PFK-PPi, EC 2.7.1.90), which catalyzes the reaction of fructose diphosphate (FDP) and inorganic phosphate to fructose 6-phosphate (F6P) and inorganic pyrophosphate. Preferred sources of PPi-dependent kinases/phosphorylases and genes coding therefor are from Propionibacterium freudenreichii (shermanii) or from potato tubers.

Further, the inorganic phosphate may be removed from the reaction by precipitation and/or complexation which may be effected by adding polyvalent metal ions, such as calcium or ferric ions capable of precipitating phosphate or by adding a complex-forming compound capable of complexing phosphate. It should be noted that also a combination of pyrophosphate formation and complexation/precipitation may be carried out.

Furthermore, the removal of inorganic phosphate may be effected by substrate phosphorylation. Thereby the inorganic phosphate is transferred to a suitable substrate, with a phosphorylated substrate being formed. The substrate is preferably selected from saccharides, e.g. disaccharides such as sucrose or maltose. When using disaccharides as substrate, a monosaccharide and a phosphorylated monosaccharide are obtained. The phosphate transfer is catalyzed by a suitable phosphorylase/kinase such as sucrose phosphorylase (EC 2.4.1.7) or maltose phosphorylase (EC 2.4.1.8). Preferred sources of these enzymes are Leuconostoc mesenteroides, Pseudomonas saccherophila (sucrose phosphorylase) and Lactobacillus brevis (maltose phosphorylase).

The phosphorylated substrate may be further reacted by additional coupled enzymatic reactions, e.g. into a galactoside (Ichikawa et al., Tetrahedron Lett. 36 (1995), 8731-8732). Further, it should be noted that phosphate removal by substrate phosphorylation may also be coupled with other phosphate removal methods as described above.

Deoxyribose 1-phosphate (dR1P), the starting compound of the method of the invention, is a rather unstable compound, the isolation of which is difficult. In a preferred embodiment of the present invention, d1RP is generated in situ from deoxyribose 5-phosphate (dR5P) which is relatively stable at room temperature and neutral pH. This reaction is catalyzed by a suitable enzyme, e.g. a deoxyribomutase (EC 5.4.2.7) or a phosphopentose mutase (PPM, EC 5.4.2.7) which may be obtained from any suitable source as outlined above. The reaction is preferably carried out in the presence of divalent metal cations, e.g. Mn²⁺ or Co²⁺ as activators. Preferred sources of deoxyribomutase are enterobacteria. Particular preferred sources of native or recombinant PPM are prokaryotic organisms such as E. coli. Recombinant PPM may be isolated from E. coli strain pHSP 275 (CNCM I-2188) deposited on Apr. 23, 1999, which is a recombinant E. coli strain transformed with a plasmid containing the E. coli deo B (phosphopentose mutase) insert. The nucleotide sequence of the PPM gene and the corresponding amino acid sequence are shown in SEQ ID NO.17 and 18 and 5 and 6.

dR5P may be generated by a condensation of glyceraldehyde 3-phosphate (GAP) with acetaldehyde. This reaction is catalyzed by a suitable enzyme, preferably by a phosphopentose aldolase (PPA, EC 4.1.2.4). The reaction exhibits an equilibrium constant favorable to the formation of the phosphorylated sugar (K_eq=[dR5P]/[acetaldehyde]×[GAP]=4.2×10³×M⁻¹). PPA forms an unstable Schiff base intermediate by interacting with the aldehyde. Particular preferred sources of native or recombinant PPA are prokaryotic organisms such as E. coli. Recombinant PPA may be isolated from E. coli strain pHSP 276 (CNCM I-2189) deposited on Apr. 23, 1999. This recombinant E. coli strain is transformed with a plasmid containing the deoC (phosphopentosealdolase) insert. The nucleotide sequence of the PPA gene and the corresponding amino acid sequence are shown in SEQ ID NO.19 and 20 and 7 and 8.

GAP is a highly unstable compound and, thus, should be generated in situ from suitable precursors which are preferably selected from fructose 1,6-diphosphate (FDP), dihydroxyacetone (DHA) and/or glycerolphosphate (GP), with FDP being preferred.

FDP can be converted by an FDP aldolase (EC 4.1.2.13) selected from FDP aldolases I and FDP aldolases II to GAP and dihydroxyacetone phosphate (K_eq=[FDP]/[GAP]×[DHAP]=10⁴M⁻¹). The two families of FDP aldolases giving identical end products (GAP and DHAP) via two chemically distinct pathways may be used for this reaction. FDP aldolase I forms Schiff base intermediates like PPA, and FDP aldolase II which uses metals (Zn²⁺) covalently bound to the active sites to generate the end products. FDP-aldolase I is characteristic to eukaryotes, although it is found in various bacteria. FDP-aldolase II is more frequently encountered in prokaryotic organisms. If FDP-aldolase reacts with FDP in the presence of acetaldehyde, the latter compound can interact with DHAP to yield an undesired condensation by-product named deoxyxylolose 1-phosphate (dX1P). Thus, the reaction is preferably conducted in a manner by which the generation of undesired side products is reduced or completely suppressed.

Particular preferred sources of native or recombinant FDP aldolases are prokaryotic or eukaryotic organisms. For example, FDP aldolase may be isolated from rabbit muscle. Further, FDP aldolase may be obtained from bacteria such as E. coli. Recombinant FDP aldolase may be isolated from recombinant E. coli strain pHSP 284 (CNCM I-2190) which is transformed with a plasmid containing the E. coli fba (fructose diphosphate aldolase) insert. The nucleotide sequence of the E. coli FDP aldolase gene and the corresponding amino acid sequence are shown in SEQ ID NO.9 and 10.

On the other hand, GAP may be generated from DHAP and ATP, with dihydroxyacetone phosphate (DHAP) and ADP being formed and subsequent isomerization of DHAP to GAP in a reaction catalyzed by a glycerokinase (GK, EC 2.7.1.30) and a triose phosphate isomerase (TIM, EC 5.3.1.1). Suitable glycerokinases are obtainable from E. coli, suitable triose phosphate isomerases are obtainable from bovine or porcine muscle.

In a still further embodiment of the present invention GAP may be generated from glycerol phosphate (GP) and O₂, with DHAP and H₂O₂ being formed and subsequent isomerization of DHAP to GAP in a reaction catalyzed by a glycerophosphate oxidase (GPO, EC 1.1.3.21) and a triose phosphate isomerase (TIM, EC 5.3.1.1). Suitable glycerophosphate oxidases are obtainable from Aerococcus viridans.

In an alternative embodiment of the present invention deoxyribose 5-phosphate (dR5P) is generated by phosphorylation of deoxyribose. Preferably this reaction is carried out in the presence of a suitable enzyme, e.g. a deoxyribokinase (dRK, EC 2.7.1.5) which may be obtained from prokaryotic organisms, particularly Salmonella typhi and in the presence of ATP. The nucleotide sequence of the Salmonella dRK gene and the corresponding amino acid sequence are shown in SEQ ID NO.11 and 12.

By the reaction as outlined above deoxyribonucleosides are obtained which contain a nucleobase which is accepted by the enzymes TP and/or PNP. TP is specific for thymidine (T), uracil (U) and other related pyrimidine compounds. PNP uses adenine, guanine, hypoxanthine or other purine analogs as substrates.

The synthesis of deoxyribonucleosides which are not obtainable by direct condensation such as deoxycytosine (dC), thus, require an additional enzymatic reaction, wherein a deoxyribonucleoside containing a first nucleobase is reacted with a second nucleobase, with a second ribonucleoside containing the second nucleobase being formed. The second nucleobase is preferably selected from cytosine and analogs thereof such as 5-azacytosine. It should be noted, however, that also other nucleobases such as 6-methyl purine, 2-amino-6-methylmercaptopurine, 6-dimethylaminopurine, 2,6-dichloropurine, 6-chloroguanine, 6-chloropurine, 6-azathymine, 5-fluorouracil, ethyl-4-amino-5-imidazole carboxylate, imidazole-4-carboxamide and 1,2,4-triazole-3-carboxamide may be converted to the corresponding deoxyribonucleoside by this nucleobase exchange reaction (Beaussire and Pochet, Nucleosides & Nucleotides 14 (1995), 805-808, Pochet et al. Bioorg. Med. Chem. Lett. 5 (1995), 1679-1684, Pochet and Dugue, Nucleosides & Nucleotides 17 (1998), 2003-2009, Pistotnik et al., Anal. Biochem. 271 (1999), 192-199). This reaction is preferably catalyzed by an enzyme called nucleoside 2-deoxyribosyltransferase (NdT, EC 2.4.2.6) which transfers the glycosyl moiety from a first deoxynucleoside to a second nucleobase, e.g. cytosine. A preferred source of native or recombinant NdT are prokaryotic organisms such as lactobacilli, particularly Lactobacillus leichmannii. Recombinant NdT may be isolated from recombinant E. coli strain pHSP 292 (CNCM I-2191) deposited on Apr. 23, 1999, which is transformed with a plasmid containing the L. leichmannii NdT (nucleoside 2-deoxyribosyltransferase) insert. The nucleotide sequence of the NdT gene and the corresponding amino acid sequence are shown in SEQ ID NO.13 and 14.

A further aspect of the present invention is a method for the in vitro enzymatic synthesis of deoxyribonucleosides comprising the steps of: (i) condensing glyceraldehyde 3-phosphate (GAP) with acetaldehyde to deoxyribose 5-phosphate (dR5P), (ii) isomerizing deoxyribose 5-phosphate to deoxyribose 1-phosphate (dRIP) and (iii) reacting deoxyribose 1-phosphate and a nucleobase, wherein a deoxyribonucleoside and inorganic phosphate are formed. Preferably, the reaction is carried out without isolating intermediate products and, more preferably, as a one-pot reaction. Further, the removal of the inorganic phosphate from the reaction is preferred.

As outlined above, the glyceraldehyde 3-phosphate may be generated from FDP, DHA and/or GP. Preferably, FDP is used as a starting material.

In order to avoid the production of undesired by-products and the toxic effects of acetaldehyde, the course of the reaction is preferably controlled by suitable means. Thus, preferably, the reaction is carried out in a manner such that the acetaldehyde concentration in step (ii) is comparatively low, e.g. less than 100 mM, particularly less than 50 mM, e.g. by adding the acetaldehyde in portions or continuously during the course of the reaction and/or by removing excess acetaldehyde. Further, it is preferred that before step (ii) excess starting materials and/or by-products, particularly fructose 1,6-diphosphate and/or deoxyxylulose 1-phosphate (dX1P), are removed. This removal may be effected by chemical and/or enzymatic methods, e.g. precipitating FDP with ferric salts or enzymatically degrading X1P via dihydroxyacetone phosphate. Alternatively or additionally the reaction conditions may be adjusted such that before step (ii) no substantial amounts, preferably less than 10 mM, of starting materials and/or by-products, particularly fructose 1,6-diphosphate and/or deoxyxylulose 1-phosphate, are present in the reaction mixture.

In still another embodiment, the present invention relates to a method for the in vitro enzymatic synthesis of deoxyribonucleosides comprising the steps of: (i) phosphorylating deoxyribose to deoxyribose 5-phosphate, (ii) isomerizing deoxyribose 5-phosphate to deoxyribose 1-phosphate and (iii) reacting deoxyribose 1-phosphate and nucleobase, wherein a deoxyribonucleoside and inorganic phosphate are formed. Preferably, these reactions are carried out with isolating intermediate products and, more preferably, as a one-pot reaction. To obtain a better yield the removal of inorganic phosphate from step (iii) is preferred.

By the process as described above naturally occurring deoxyribonucleosides such as dA, dG, dT, dU and dT but also analogs thereof containing non-naturally occurring nucleobases and/or non-naturally occurring deoxyribose sugars such as 2′-deoxy-3′-azido-deoxyribose or 2′-deoxy-4′-thio-deoxy-ribose may be produced.

The deoxyribonucleosides obtained may be converted to further products according to known methods. These further reaction steps may comprise the synthesis of deoxyribonucleoside mono-, di- or triphosphates, of H-phosphonates or phosphoramidites. Additionally or alternatively, labelling groups such as radioactive or chemical labelling groups may be introduced into the deoxyribonucleosides.

Still a further aspect of the present invention is the use of an isolated nucleic acid molecule encoding a nucleoside 2-deoxyribosyl transferase (NdT, EC 2.4.2.6) for the preparation of an enzyme in an in vitro enzymatic synthesis process, wherein a deoxyribonucleoside containing a first nucleobase is reacted with a second nucleobase, with a deoxyribonucleoside containing the second nucleobase being formed. The second nucleobase is preferably selected from cytidine and analogs thereof, 2,6-dichloro-purine, 6-chloro-guanine, 6-chloro-purine, 6-aza-thymine and 5-fluoro-uracil. The first nucleobase is preferably selected from thymine, guanine, adenine or uracil. More preferably, the nucleic acid molecule encoding an NdT comprises (a) the nucleotide sequence shown in SEQ ID NO.13 or its complementary sequence, (b) a nucleotide sequence corresponding to the sequence of (a) in the scope of degeneracy of the genetic code or (c) the nucleotide sequence hybridizing under stringent conditions to the sequence (a) and/or (b). Apart from the sequence of SEQ ID NO.13 the present invention also covers nucleotide sequences coding for the same polypeptide, i.e. they correspond to the sequence within the scope of degeneracy of the genetic code, and nucleotide sequence hybridizing with one of the above-mentioned sequences under stringent conditions. These nucleotide sequences are obtainable from SEQ ID NO.13 by recombinant DNA and mutagenesis techniques or from natural sources, e.g. from other Lactobacillus strains.

Stringent hybridization conditions in the sense of the present invention are defined as those described by Sambrook et al., Molecular Cloning, A Laboratory Manual, Cold Spring Harbor Laboratory Press (1989), 1.101-1.104. According to this, hybridization under stringent conditions means that a positive hybridization signal is still observed after washing for one hour with 1×SSC buffer and 0.1% SDS at 55° C., preferably at 62° C. and most preferred at 68° C., in particular, for one hour in 0.2×SSC buffer and 0.1% SDS at 55° C., preferably at 62° C. and most preferred at 68° C.

Moreover, the present invention also covers nucleotide sequences which, on nucleotide level, have an identity of at least 70%, particularly preferred at least 80% and most preferred at least 90% to the nucleotide sequence shown in SEQ ID NO.13. Percent identity are determined according to the following equation:

$I=\frac{n}{L}\times 100$

wherein I are percent identity, L is the length of the basic sequence and n is the number of nucleotide or amino acid matching between the selected sequence and that of the basic sequence.

Still another subject matter of the present invention is a recombinant vector comprising at least one copy of the nucleic acid molecule as defined above, operatively linked with an expression control sequence. The vector may be any prokaryotic or eukaryotic vector. Examples of prokaryotic vectors are chromosomal vectors such as bacteriophages (e.g. bacteriophage Lambda) and extrachromosomal vectors such as plasmids (see, for example, Sambrook et al., supra, Chapter 1-4). The vector may also be a eukaryotic vector, e.g. a yeast vector or a vector suitable for higher cells, e.g. a plasmaid vector, viral vector or plant vector. Suitable eukaryotic vectors are described, for example, by Sambrook et al., supra, Chapter 16. The invention moreover relates to a recombinant cell transformed with the nucleic acid or the recombinant vector as described above. The cell may be any cell, e.g. a prokaryotic or eukaryotic cell. Prokaryotic cells, in particular, E. coli cells, are especially preferred.

The invention refers to an isolated polypeptide having NdT activity encoded by the above-described nucleic acid and its use for the preparation of deoxyribonucleosides. Preferably, the polypeptide has the amino acid sequence shown in SEQ ID NO.14 or an amino acid sequence which is at least 70%, particularly preferred at least 80% and most preferred at least 90% identical thereto, wherein the identity may be determined as described above.

Finally, the present invention also relates to the use of isolated nucleic acid molecules having thymidine phosphorylase (TP), purine nucleoside phosphorylase (PNP), phosphopentose mutase (PPM), phosphopentose aldolase (PPA), FDP aldolase and deoxyribokinase (dRK) activity for the preparation of an enzyme for a method for the in vitro synthesis of deoxynucleosides. Preferably, these nucleic acids are selected (a) from a nucleotide sequence shown in SEQ ID NO.1, 3, 5, 7, 9 or 11 or their complementary sequences, (b) a nucleotide sequence corresponding to a sequence of (a) within the scope of degeneracy of the genetic code or (c) a nucleotide sequence hybridizing under stringent conditions to a sequence (a) and/or (b).

Isolated polypeptides having TP, PNP, PPM, PPA, FDP aldolase or dRK activity encoded by the above-described nucleic acids may be used for the preparation of deoxyribonucleosides. Preferably, these polypeptides have the amino acid sequence shown in SEQ ID NO.2, 4, 16, 6, 18, 8, 20, 10 or 12 or an amino acid sequence which is at least 70%, particularly preferred at least 80% and most preferred at least 90% identical thereto, wherein the identity may be determined as described above.

An isolated nucleic acid molecule encoding a dRK may be used for the preparation of an enzyme for an in vitro method for the enzymatic synthesis of deoxyribonucleosides comprising the step of phosphorylating deoxyribose to deoxyribose 5-phosphate, wherein said nucleic acid molecule comprises (a) the nucleotide sequence shown in SEQ ID NO. 11 or its complementary sequence, (b) a nucleotide sequence corresponding to the sequence of (a) in the scope of the degeneracy of the genetic code or (c) a nucleotide sequence hybridizing under stringent conditions to the sequence of (a) and/or (b). Correspondingly, an isolated polypeptide having dRK activity is suitable for an in vitro method for the enzymatic synthesis of deoxyribonucleosides as outlined above.

The E. coli strains pHSP 282 (CNCM I-2186), pHSP 283 (CNCM I-2187), pHSP 275 (CNCM I-2188), pHSP 276 (CNCM 2189), pHSP 284 (CNCM I-2190) and pHSP 292 (CNCM I-2191) were deposited according to the regulations of the Budapest Treaty on Apr. 23, 1999 at the Collection Nationale de Culture de Microorganismes, Institut Pasteur, 25, Rue de Docteur Roux, 75724 Paris Cedex 15.

DESCRIPTION OF FIGURES

FIG. 1 shows the synthesis of dR5P according to Example 12.

FIG. 2 shows the synthesis of deoxyadenosine according to Example 12.

FIG. 3 shows the synthesis of deoxyadensine according to Example 13.

FIG. 4 shows the synthesis of dG-NH₂ according to Example 14.

EXAMPLE 1

Sources of Enzymes

L-glycerol 3-phosphate oxidase (1.1.3.21) from Aerococcus viridans, sucrose phosphorylase (2.4.1.7), fructose 6-phosphate kinase (2.7.1.90) from Propionibacterium freudenreichii, rabbit muscle aldolase (RAMA), formate dehydrogenase, glycerolphosphate dehydrogenase (GDH), triosephosphate isomerase (TIM), catalase, glycerol 3-phosphate oxidase and maltose phosphorylase were obtained from commercial sources (Roche Diagnostics, Sigma) or as described in the literature.

FDP aldolase II (4.1.2.13), phosphopentose aldolase (PPA, EC 4.1.2.4), phosphopentose mutase (PPM, EC 5.4.2.7), thymidine phosphorylase (TP, EC 2.4.2.4), purine nucleoside phosphorylase (PNP, EC 2.4.2.1), nucleoside 2-deoxyribosyl transferase (NdT, EC 2.4.2.6) were obtained from E. coli strains deposited at CNCM (see above).

EXAMPLE 2

Protocol of the Synthesis of Deoxyadenosine

Reaction mixture A was prepared by adding acetaldehyde (final concentration 250 mM), FDP aldolase II (0.5 U/ml), PPA (2.5 U/ml) to 20 ml of 100 mM fructose-1,6-diphosphate (FDP), pH 7.6 and incubating overnight at 4° C.

Mixture B was prepared by adding MnCl₂ (final concentration 0.6 mM), glucose 1,6-diphosphate (15 μM), PPM (1.5 U/ml), PNP (0.4 U/ml), SP (1.5 U/ml) pentosephosphate aldolase, PPA (2 U/ml) and FDP aldolase II (0.5 U/ml) to 10 ml 0.9 M sucrose, pH 7.6, at room temperature.

2 ml of A were added over B at a temperature of 20° C. After 1 hour 2.5 ml A were added. After another hour 3.0 ml A were added. After another 1.5 h 3.5 ml A were added. After another 1.5 h 4 ml A were added and after another 1-1.5 h 5 ml A were added and left to stand overnight.

At each time of addition of A the amounts of FDP, dR5P, dX1P and dA in the reaction mixture were determined and the yield was calculated. The concentration of acetaldehyde was kept between 20-30 mM. The results are shown in Table 1:

	TABLE 1
	Time	Volume	Concentrations (mM)	Yield (mmol)
	(h)	(ml)	dR5P	dA	dX1P	dA
	0	12	4	0	1.2	0
	1	12	3.4	3.2	1	0.04
	2	14.5	7.9	8.0	2.6	0.12
	3.5	17.5	13	16.2	4.3	0.28
	5	21	11.7	21.7		0.46
	6	25		23.7		0.59
	22	30	11	40.4	13.2	1.21
	30	30		50.3		1.51
	54	30	8.9	60.6		1.82

The starting amount of FDP was 1.92 mmol. The amount after completion of reaction was 0.150 mmol. Thus, 1.77 mmol were consumed, theoretically corresponding to 3.54 mmol equivalents dA. The amount of dA formed was 1.82 mmol, leading to a yield of 51.4% based on the amount of FDP.

EXAMPLE 3

Removal of Excess FDP by Means of FeCl₃

1.4 g (2.55 mmol) trisodium-fructose-1,6-disphosphate-octahydrate and 430 μl (335 mg, 7.6 mmol) acetaldehyde were dissolved in 15 ml of water at 4° C. A pH of 7.9 was adjusted by means of sodium hydroxide solution. 150 U pentosephosphate aldolase (PPA) were added, and cold water (4° C.) was added to give 20 ml. After addition of 50 U E. coli aldolase II the mixture was stored at 4° C. After 2 h another 75 U PPA and 50 μl acetaldehyde (390 mg, 8.9 mmol) were added. After 20 h 500 U triosephosphate isomerase (TIM) were added. After 120 h the solution contained about 68 mM FDP, about 12 mM dX1P and about 45 mM dR5P. The reaction was stopped by adding 900 μl of a 2 M solution of iron(III) chloride in 0.01 M hydrochloric acid. The precipitate was centrifuged and washed, the resulting solution contained about 4 mM dX1P, about 9 mM FDP and about 25 mM dR5P.

EXAMPLE 4

Removal of Excess FDP and dX1P by Degradation Via DHAP

576 mg (1.05 mmol) trisodium-fructose-1,6-disphosphate-octahydrate were dissolved in 8 ml water, and the pH was adjusted at 8.1 by means of sodium hydroxide solution. 75 U PPA and 27 U rabbit muscle aldolase (RAMA) were added, and water was added to give 10 ml. 570 μl (440 mg, 10 mmol) acetaldehyde were added. The reaction was stored at 4° C. After 100 h the solution contained about 110 mM dX1P, about 5 mM FDP and about 85 mM dR5P (about 870 μmol). The reaction was stopped by adding hydrochloric acid until a pH of 2 was reached. After adding sodium hydroxide solution to give a pH of 5.5 the solution was stored.

For removing dX1P the acetaldehyde was evaporated and the solution was diluted with water to reach 30 ml. It was mixed with 3 ml 2.65 M sodium formate solution (8 mmol), and sodium hydroxide solution was added until a pH of 7.4 was reached. 23 U formate dehydrogenase (FDH), 6 mg NADH, 16 U RAMA and 20 U glycerolphosphate dehydrogenase (GDH) were added.

After 24 h at room temperature the concentrations of dX1P and FDP are below 3 mM, the loss of dR5P is less than 10%.

EXAMPLE 5

Preparation of dR5P Via G3P

1.1 g (2.0 mmol) trisodium-fructose-1,6-disphosphate-octahydrate were dissolved in 8 ml water. 1.58 mol of a 2.65 M sodium formate solution (4.2 mmol) and 14.2 mg NADH were added. A pH of 7.0 was adjusted by means of NaOH. After addition of 36 U RAMA, 50 U triosephosphate isomerase (TIM), 34 U GDH and 35 U FDH water was added to give 12 ml.

After incubation of 40 h at room temperature the FDP content was below 3 mM. The enzymes were denatured by acidification with hydrochloric acid to reach a pH of 2. Subsequently, the pH of the solution was adjusted at 4 and the solids were centrifuged and filtered off, respectively. Through dilution during purification a total volume of 25 ml was reached which contained about 160 mM of glycerol-3-phosphate (G3P).

4 ml of this solution (about 640 μmol G3P) were adjusted at a pH of 7.8 by means of sodium hydroxide solution. 7.8 kU catalase, 500 U TIM and 13 U glycerol 3-phosphate oxidase are added. The mixture was stirred very slowly in an open flask. After 30 min 18 U PPA were added. Acetaldehyde was added in portions of 30 μl (23.5 mg, 530 μmol) after 30, 60, 120, 180 and 240 min. After 24 h another 15 U PPA, 2.5 kU TIM and 100 μl (78 mg, 1.8 mmol) acetaldehyde were added. After 30 h the batch is sealed after addition of another 100 μl acetaldehyde. After a total of 45 h a concentration of about 60 mM dR5P was achieved and the reaction is completed. For preparing 2′-deoxyadenosine (e.g. Example 7) excess acetaldehyde must be distilled off.

EXAMPLE 6

Preparation of a dR5P Solution Containing Small Amounts of dX1P or FDP

A solution of 60 mmol/l FDP and 120 mmol/l acetaldehyde having pH 7.4 was kept at a temperature of 15° C. 5 ml thereof were mixed with 4 U aldolase II, 2 U TIM and 40 U PPA and kept at 15° C. After 4, 8.5, 16.5 and 24 h 12 U PPA and 100 μl of a 34 vol.-% solution of acetaldehyde in water (26.4 mg, 600 μmol) were added each. After 40 h the solution was allowed to reach room temperature. After 90 h the reaction solution had reached concentrations of about 3 mM FDP, about 4 mM dX1P and at least 70 mM dR5P. For stopping the reaction and removing acetaldehyde about 20% of the volume were distilled off.

EXAMPLE 7

Preparation of Deoxyadenosine (dA) from dR5P by Means of Barium Acetate

dR5P was used in the form of a solution prepared according to Examples 3-6. For instance, 10 ml of a solution of Example 6 diluted to have 70 mM dR5P (700 μmol dR5P) were mixed with 40 mg (300 μmol) adenine, 41 μg (50 nmol) tetracyclohexylammonium-glucose-1,6-disphosphate, 396 μg (2 μmol) manganese-II-acetate-tetrahydrate, 10 U pentosephosphate mutase (PPM) and 30 U purine-nucleoside phosphorylase (PNP). After 3 h another 27 mg (200 μmol) adenine and 26 mg (100 μmol) barium acetate were added.

A further amount of 26 mg barium acetate was added after 4 h, one of 40 mg adenine after 7 h. After 10 h the reaction was completed. The solution had a concentration of 45 mM dA.

EXAMPLE 8

Preparation of Deoxyadenosine (dA) from dR5P by Means of Sucrose Phosphorylase

10 ml of a solution of Example 6 diluted to 55 mM dR5P (550 μmol dR5P) were mixed with 81 mg (600 μmol) adenine, 41 μq (50 nmol) tetracyclohexylammonium-glucose-1,6-disphosphate, 396 μg (2 μmol) manganese-II-acetate-tetrahydrate, 10 U pentosephosphate mutase (PPM) 15 U purine nucleoside phosphorylase (PNP), 25 U sucrose phosphorylase and 340 mg (1 mmol) cane sugar.

After 3 h at room temperature the reaction was completed. The solution had a concentration of about 50 mM dA.

EXAMPLE 9

Preparation of Deoxyadenosine (dA) from dR5P by Means of Maltose Phosphorylase

10 ml of a solution of dR5P diluted to 55 mM were mixed at pH 7.0 with 81 mg (600 μmol) adenine, 41 μg (50 nmoles) glucose 1,6-diphosphate, 396 μg (2 μmoles) manganese II-acetate tetrahydrate, 5 units pentose phosphate mutase (PPM), 10 units purine nucleoside phosphorylase, (PNP), 20 units maltose phosphorylase and 1080 mg (3 mmoles) maltose.

After 12 h at room temperature the reaction was completed. The solution had a concentration of 49 mM dA.

EXAMPLE 10

Preparation of Deoxycytosine (dC) from dR5P by Means of Sucrose Phosphorylase

20 ml of a solution of dR5P diluted to 70 mM were mixed at pH 7.0 with 5.4 mg adenine (0.04 mmoles), 155 mg cytosine (1.4 mmoles), 82 μg (100 nmoles) glucose 1,6-diphosphate, 792 μg (4 μmoles) manganese II-acetate-tetrahydrate, 20 units PPM, 30 units PNP, 50 units 2-deoxyribosyl transferase (NdT), 50 units sucrose phosphorylase and 2.05 g (6 mmoles) sucrose.

After 18 h at 30° C. the solution had a concentration of 62 mM dC.

EXAMPLE 11

Preparation of Deoxyguanosine (dG) from dR5P by Means of Sucrose Phosphorylase

20 ml of a solution of dR5P diluted to 70 mM were mixed at pH 7.0 with 91 mg guanine (0.6 mmoles), 82 μg (100 nmoles) glucose 1,6-diphosphate, 792 μg (4 μmoles) manganese II-acetate-tetrahydrate, 20 units PPM, 10 units PNP, 20 units sucrose phosphorylase and 2.05 g (6 mmoles) sucrose.

After 18 h at 37° C. the dG formed corresponds to 0.5 mmoles.

EXAMPLE 12

Two Step Procedure of dA Synthesis

In the first step dR5P was prepared by adding FDP-Aldolase II (AldII) from E. coli, pentosephosphate aldolase (PPA) from E. coli and triosephosphate isomerase (TIM) from E. coli to fructose-1,6-bisphosphate (FDP) and acetaldehyde (AcAld) essentially according to Ex. 6. FDP trisodium salt was mixed in a final concentration of 75 mM with AcAld (100 mM final concentration). The pH was adjusted to 7.4 by addition of sodium hydroxide. The reaction was started by adding PPA (12 kU/l), Ald II (0.3 kU/l) and TIM (2.5 kU/l). At 4 h 117 mM AcAld, at 7 h 117 mm AcAld, PPA 6 kU/l, TIM 2.5 kU/l and at 12 h 117 mM AcAld were added. The reaction was run at 21° C. Conversion was monitored by enzymatical assay using step by step glycerol-3-phosphate dehydrogenase (GDH), rabbit muscle aldolase (RAMA), trisosephosphate isomerase (TIM), pentosephosphate aldolase (PPA) in the presence of NADH (0.26 mM in 300 mM triethanol amine buffer pH 7.6). Conversion is shown in FIG. 1.

After yielding approx. 95 mM dR5P the enzymes were deactivated by heating to 65° C. for 10 min. and excess of AcAld was removed by evaporation. In the second step dR5P in a final concentration of 64 mM was converted to deoxyadenosine (dA) by adding adenine (A, final concentration 58 mM) in the presence of 300 μM MnCl₂, 5 μM Glucose-1.6-bisphosphate, pentosephosphate mutase from E. coli (PPM, 2 kU/l), purine nucleoside phosphorylase from E. coli (PNP, 1 kU/l). The synthesis was run at 20° C., pH 7.4. In one experiment 200 mM sucrose and 0.6 kU/l sucrose phosphorylase (SP) from Leuconostoc mes. were added at t=2 h (see arrow in FIG. 2, rhombus, solid line), in a second experiment addition of SP was omitted (squares, dotted line). The conversion was monitored by RP-HPLC (column Hypersil ODS 5 μm, 250×4.6 mm; eluent: 30 mM potassium phosphate, 5 mM tetrabutyl ammoniumhydrogensulfate pH 6.0/1% acetonitrile, flow rate: 1 ml/min, column temp.: 35° C., det.: UV at 260 nm) and is shown in FIG. 2.

EXAMPLE 13

dR5P was prepared by adding FDP-Aldolase II (AldII) from E. coli, pentosephosphate aldolase (PPA) from E. coli and trisosephosphate isomerase (TIM) from E. coli to fructose-1,6-bisphosphate (FDP) and acetaldehyde (AcAld) essentially according to Ex. 6. Excess of AcAld was removed by evaporation. dR5P in a final concentration of 60 mM was converted to deoxyadenosine (dA) by adding adenine (A, final concentration 58 mM) in the presence of 300 μM MnCl₂, 5 μM Glucose-1.6-bisphosphate, pentosephosphate mutase from E. coli (PPM, 1.5 kU/l), purine nucleoside phosphorylase from E. coli (PNP, 1 kU/l). The synthesis was run at 20° C., pH 7.4. After 24 h sucrose in a final concentration of 200 mM and sucrose phosphorylase from Leuconsotoc mes. (1 kU/l) were added. Conversion was monitored by RP-HPLC (dA, A, see ex. 12) resp. enzymatical assay (dR5P, using step by step glycerol-3-phosphate dehydrogenase (GDH), rabbit muscle aldolase (RAMA), trisosephosphate isomerase (TIM), pentosephosphate aldolase (PPA) in the presence of NADH (0.26 mM in 300 mM Triethanol amine buffer pH 7.6) and phosphomolybdate complexing of inorg. phosphate (Sigma, Proc. No. 360-UV). This is shown in FIG. 3.

EXAMPLE 14

dR5P was essentially prepared according to Ex. 6. dR5P in a final concentration of 80 mM was then converted to deoxy-6-aminoguanosine (dG-NH₂) by adding 2,6-Diaminopurine (DAP, final concentration 77 mM) in the presence of 200 mM sucrose, 300 μM MnCl₂, 5 μM Glucose-1.6-bisphosphate, pentosephosphate mutase from E. coli (PPM, 2.5 kU/l), purine nucleoside phosphorylase from E. coli (PNP, 1 kU/l), sucrose phosphorylase from Leucoonostoc mes. (SP, 1.5 kU/l). The synthesis was run at 20° C. pH 7.4. After 2.5 h, 5 h and 20.5 h additional amounts of enzymes were added: 2.5 h PPM (2.5 kU/l), PNP (1 kU/l, SP (1.5 kU/l), 5 h PPM (2.5 kU/l), SP (1.5 kU/l), 20.5 h: PPM (2.5 kU/l), SP (1.5 kU/l). The conversion was monitored by RP-HPLC (column Hypersil ODS 5 μm, 250×4.6 mm; eluent: 30 mM potassium phosphate, 5 mM tetrabutyl ammoniumhydrogensulfate pH 6.0/1% acetonitrile, flow rate: 1 ml/min, column temp.: 35° C., det.: UV at 216 nm) and is shown in FIG. 4.

Claims

1-45. (canceled)

46. A method for in vitro enzymatic synthesis of a deoxyribonucleoside comprising reacting deoxyribose 1-phosphate (dR1P) and a nucleobase to form a deoxyribonucleoside and an inorganic phosphate.

47. The method of claim 46, further comprising removing the inorganic phosphate.

48. The method of claim 46, wherein said reacting comprises catalyzing said dR1P and said nucleobase with a thymidine phosphorylase (TP, EC 2.4.2.4.) or a purine nucleoside phosphorylase (PNP, EC 2.4.2.1.).

49. The method of claim 47, comprising removing the inorganic phosphate by one of: (i) converting the inorganic phosphate to inorganic pyrophosphate, (ii) precipitating the inorganic phosphate, (iii) complexing the inorganic phosphate, or (iv) phosphorylating a substrate with the inorganic phosphate.

50. The method of claim 47, comprising removing the inorganic phosphate by phosphorylating a substrate with the inorganic phosphate.

51. The method of claim 46, wherein the nucleobase is selected from the group consisting of thymine, uracil, adenine, guanine, hypoxanthinine and an analog thereof.

52. The method of claim 51, wherein said analog is selected from the group consisting of: 2-thio-uracil, 6-aza-uracil, 5-carboxy-2-thio-uracil, 6-aza-thymine, 6-aza-2-thio-thymine and 2,6-diamino-purine.

53. The method of claim 46, further comprising reacting said inorganic phosphate with fructose-diphosphate (FDP) to form pyrophosphate and fructose-6-phosphate (F6P).

54. The method of claim 53, wherein said reacting comprises catalyzing said inorganic phosphate with said FDP with a Ppi-dependent phosphofructokinase (PFK-Ppi, EC 2.7.1.90).

55. The method of claim 46, further comprising reacting said inorganic phosphate with a disaccharide to form a monosaccharide and a phosphorylated monosaccharide.

56. The method of claim 55, wherein the disaccharide is sucrose or maltose.

57. The method of claim 56, wherein said reacting comprises catalyzing said inorganic phosphate and said disaccharide with a sucrose phosphorylase (EC 2.4.1.7) or a maltose phosphorylase (EC 2.4.1.8).

58. The method of claim 46, further comprising generating dR1P by isomerizing deoxyribose 5-phosphate (dR5P) prior to reacting said dR1P with a nucleobase.

59. The method of claim 58, comprising isomerizing said dR5P with a phosphopentose mutase (PPM, EC 5.4.2.7).

60. The method of claim 58, further comprising forming the dR5P by condensing glyceraldehyde 3-phosphate (GAP) with acetaldehyde prior to isomerizing said dR5P.

61. The method of claim 60, wherein said condensing comprises catalyzing condensing of GAP with acetaldehyde with a phosphopentose aldolase (PPA, EC 4.1.2.4).

62. The method of claim 60, further comprising enzymatically generating said GAP from fructose 1,6-diphosphate, dihydroxyacetone (DHA) or glycerolphosphate (GP) prior to said condensing.

63. The method of claim 58, comprising generating said deoxyribose 5-phosphate by phosphorylating deoxyribose prior to isomerizing said dR5P.

64. The method of claim 63, wherein said phosphorylating comprises catalyzing of deoxyribose with a deoxyribokinase (dRK, EC 2.7.1.15.).

65. The method of claim 64, wherein said dRK is encoded by (a) the nucleotide sequence of SEQ ID NO: 11, (b) a nucleotide sequence encoding the protein encoded by SEQ ID NO: 11 or (c) a nucleotide sequence which hybridizes under stringent conditions to the complementary sequence of (a) or (b).

66. The method of claim 62, comprising reacting fructose 1,6-diphosphate with an FDP-aldolase I or an FDP-aldolase II to form said GAP.

67. The method of claim 62, comprising forming said GAP by reacting DHA with ATP to form dihydroxyacetone phosphate (DHAP), followed by catalyzing isomerization of said DHAP to GAP with a glycerokinase (GK, EC 2.7.1.30) and a triose phosphate isomerase (TIM, EC 5.3.1.1).

68. The method of claim 62, comprising forming said GAP by reacting GP with O2 to form dihydroxyacetone phosphate (DHAP) and H2O2, followed by catalyzing isomerization of said DHAP to GAP with a glycerophosphate oxidase (GPO, EC 1.1.3.21) and a triose phosphate isomerase (TIM, EC 5.3.1.1).

69. The method of claim 46, further comprising reacting said deoxyribonucleoside with a second nucleobase to form a second deoxyribonucleoside containing the second nucleobase.

70. The method of claim 69, comprising catalyzing said reacting with a nucleoside 2-deoxyribosyl transferase (NdT, EC 2.4.2.6).

71. The method of claim 70, wherein said NdT is encoded by (a) a nucleic acid molecule consisting of the nucleotide sequence of SEQ ID NO: 13, (b) a nucleic acid molecule consisting of a nucleotide sequence encoding the protein encoded by SEQ ID NO: 13 or (c) a nucleic acid molecule which hybridizes under stringent conditions to the nucleic acid molecule of (a) or (b).

72. The method of claim 69, wherein said second nucleobase is selected from the group consisting of cytosine and a cytosine analog.

73. The method of claim 69, wherein said second nucleobase is selected from the group consisting of 5-aza-cytosine, 2,6-dichloro-purine, 6-aza-thymine and 5-fluoro-uracil.

74. A method for the in vitro enzymatic synthesis of a deoxyribonucleoside comprising:

(i) condensing glyceraldehyde 3-phosphate (GAP) with acetaldehyde to form deoxyribose 5-phosphate (dR5P),

(ii) isomerizing said dR5P to deoxyribose 1-phosphate (dR1P), and

(iii) reacting said dR1P and a nucleobase, to form said deoxyribonucleoside and an inorganic phosphate.

75. The method of claim 74, further comprising removing the inorganic phosphate.

76. The method of claim 75, comprising removing the inorganic phosphate by phosphorylation of a substrate with the inorganic phosphate.

77. The method of claim 74, comprising carrying out the complete reaction of steps (i) to (iii) without isolating intermediate products.

78. The method of claim 74, comprising generating said GAP from fructose 1,6-diphosphate (FDP), dihydroxy-acetone (DHA) or glycerolphosphate (GP) prior to said condensing of GAP.

79. The method of claim 74, further comprising removing excess acetaldehyde before step (ii).

80. The method of claim 78, further comprising generating said GAP and removing excess starting materials or by-products before step (ii).

81. The method of claim 80, wherein said excess starting material is fructose 1,6-diphosphate and said excess by-product is deoxyxylulose 1-phosphate (dX1P).

82. The method of claim 78, comprising generating GAP from FDP, and generating DXP1 as an excess by-product thereby.

83. A method for the in vitro enzymatic synthesis of a deoxyribonucleoside comprising:

(i) phosphorylating deoxyribose to deoxyribose 5-phosphate (dR5P),

(ii) isomerizing said dR5P to deoxyribose 1-phosphate (dR1P), and

(iii) reacting said dR1P and a nucleobase to form said deoxyribonucleoside and an inorganic phosphate.

84. The method of claim 83, further comprising removing the inorganic phosphate.

85. The method of claim 84, comprising removing the inorganic phosphate by phosphorylating a substrate with the inorganic phosphate.

86. The method of claim 83, comprising conducting the complete reaction of steps (i) to (iii) without isolating intermediate products.

87. A method for preparing an enzyme for an in vitro method for enzymatic synthesis of a deoxyribonucleoside, comprising reacting (i) an isolated nucleic acid molecule encoding a nucleoside 2-deoxyribosyl transferase (NdT, EC 2.4.2.6) with (ii) a deoxyribonucleoside containing a first nucleobase, wherein said nucleic acid molecule comprises (a) the nucleotide sequence shown in SEQ ID NO: 13, (b) a nucleotide sequence encoding the protein encoded by SEQ ID NO: 13 or (c) a nucleotide sequence hybridizing under stringent conditions to the complementary sequence of (a) or (b), and wherein said deoxyribonucleoside containing a first nucleobase is further reacted with a second nucleobase to form a deoxyribonucleoside containing said second nucleobase.

88. The method of claim 87, wherein the second nucleobase is selected from the group consisting of cytidine and a cytidine analog.

89. The method of claim 88, wherein the analog is selected from the group consisting of: 6-methyl purine, 2-amino-6-methylmercaptopurine, 6-dimethylaminopurine, 5-azacytidine, 2,6-dichloropurine, 6-chloroguanine, 6-chloropurine, 6-azathymine, 5-fluorouracil, ethyl-4-amino-5-imidazole carboxylate, imidazole-4-carboxamide and 1,2,4-triazole-3-carboxamide.

90. The method of claim 87, wherein the first nucleobase is selected from the group consisting of adenine, guanine, thymine, uracil and hypoxanthine.

91. The method of claim 87, comprising containing the nucleic acid molecule in a recombinant vector in operative linkage with an expression control sequence.

92. The method of claim 81, comprising containing the nucleic acid in a recombinant cell.

93. A method for preparing an enzyme for an in vitro method for enzymatic synthesis of a deoxyribonucleoside, comprising reacting (i) an isolated nucleic acid molecule encoding a deoxyribokinase (dRK, EC 2.7.1.5) with (ii) deoxyribose, further comprising phosphorylating said deoxyribose to deoxyribose 5-phosphate, wherein said nucleic acid molecule comprises (a) the nucleotide sequence shown in SEQ ID NO: 11, (b) a nucleotide sequence encoding the protein encoded by SEQ ID NO: 11 or (c) a nucleotide sequence hybridizing under stringent conditions to the complementary sequence of (a) or (b).

94. A method for synthesizing a deoxyribonucleoside in vitro, comprising contacting a mixture containing deoxyribose and phosphate with an enzyme having NdT activity to form deoxyribose 5-phosphate and obtaining deoxyribose 5-phosphate therefrom.