Pyrimidine nucleoside bases and purines

Two Nitrogen Atoms (it is self-sub divided into 1,2-Heterocycles, 1,3-Heterocycles Monocyclic Pyrimidines and Hydropyrimidines Except Pyrimidine Nucleoside Bases and Nucleosides, Annulated Pyrimidines Except Purines, Pteridines, and Flavins, Pyrimidine Nucleoside Bases and Purines, Nucleotides and Nucleosides, Nucleic Acids, Pyrazines, and Hydropyrazines). 

Pyrimidine nucleoside bases and purines Artificial nucleobases for hole transport 07Y204. 

Fig. 15.1. The four bases found in the nucleic acids. Uracil occurs in RNA and is substituted by the analogous thymine (5-methyluracil) in DNA. Uracil is the keto tautomer of 2,4-dihydroxy pyrimidine with two donors N(1)H, N(3)H and two acceptors 0(2), 0(4). Cytosine is the keto tautomer of 4-amino, 2-hydroxy pyrimidine with three donors N(4)H2, N(1)H and two acceptors 0(2), N(3). Adenine is 6-aminopurine with three donors N(6)H2, N(9)H and three acceptors N(l), N(3), N(7). Guanine is the keto tautomer of 2-amino, 6-hydroxy purine with three donors N(2)H2, N(9)H and three acceptors, N(3), N(7), 0(6). In the nucleosides, pyrimidine N(l) and purine N(9) are substituted by ribose or deoxyribose (see Fig. 17.1)...

There are some additional possibilities for proton tautomerism with adenine, guanine, and cytosine (Fig. 15.5), where one of the protons can move from one ring nitrogen atom to another one. This type of tautomerism is restricted to the free bases and cannot occur in the nucleosides where pyrimidine N(l) and purine N(9) are substituted by the furanose moiety. 

Table 193 gives a comparison of the separations of nucleobases and nucleosides on paper and on layers of cellulose, silica gel G and ECTEOLA-cellulose. The extensive agreement of the hJK/-values of the purine bases and purine nucleosides on the cellulose and ECTEOLA-ceUulose layers and on paper, is striking appreciably higher LB/-values were found on silica gel G. The various pyrimidines and pyrimidine-ribonucleosides have very nearly identical LB/-values on the three layers and on paper. A better separation of the purine and pyrimidine bases from the corresponding ribonucleosides is achived on cellulose and ECTEOLA cellulose layers than on sihca gel G. These three adsorbents are about equally useful for fractionating the nucleosides. 

Section 28 2 Nucleosides are carbohydrate derivatives of pyrimidine and purine bases The most important nucleosides are derived from d ribose and 2 deoxy D ribose... 

Section 28.2 Nucleosides are car bohydrate derivatives of pyrimidine and purine bases. 

Nucleoside (Section 28.2) The combination of a purine or pyrimidine base and a carbohydrate, usually ribose or 2-deoxyribose. 

Nucleosides are much more water-soluble than the free bases because of the hydrophilicity of the sugar moiety. Like glycosides (see Chapter 7), nucleosides are relatively stable in alkali. Pyrimidine nucleosides are also resistant to acid hydrolysis, but purine nucleosides are easily hydrolyzed in acid to yield the free base and pentose. 

Treatment of the allylic sulfoxide 1227 a with diisopropylethylamine (DIPEA) or of 1227 b with N-trimethylsilyldiethylamine 146 and TMSOTf 20 leads in ca. 90% yield to the quaternary amino derivatives 1228 and 1229 and HMDSO 7 [36] (Scheme 8.15). Tetramethylene sulfoxide 1230 reacts with silylated thymine 1231 in the presence of three equivalents of TMSOTf 20 to give the 4 -thio-nucleoside analogue 1232 and HMDSO 7 [37]. Other silylated pyrimidine, pyridine, and purine bases react analogously with cyclic sulfoxides to give 4 -thio-nucleoside analogues [37, 37a, 38]. 

A different strategy has been applied in our work, that emphasizes the importance of DNA stability on hole transfer within double-stranded DNA. This work is based on determination of the overall yield of oxidized nucleosides that arise from the conversion of initially generated purine and pyrimidine radical cations within DNA exposed to two-photon UVC laser pulses. On the one hand, this work benefits from the excellent current knowledge of chemical reactions involving the radical cations of DNA bases, and on the other hand, from major analytical improvements that include recent availability of the powerful technique of high performance liquid chromatography-electrospray ionization-tandem mass spectrometry (CLHP-ESI-MS/MS) [16-18]. 

Figure 27.1 Three common nucleoside triphosphate derivatives that can be incorporated into oligonucleotides by enzymatic means. The first two are biotin derivatives of pyrimidine and purine bases, respectively, that can be added to an existing DNA strand using either polymerase or terminal transferase enzymes. Modification of DNA with these nucleosides results in a probe detectable with labeled avidin or streptavidin conjugates. The third nucleoside triphosphate derivative contains an amine group that can be added to DNA using terminal transferase. The modified oligonucleotide then can be labeled with amine-reactive bioconjugation reagents to create a detectable probe.

In view of the difficulty of hydrolyzing the pyrimidine nucleosidic linkages, ribonucleic acids have been hydrolyzed to a mixture of purine bases and pyrimidine nucleotides which is then separated by paper chromatography.132, 163 164 This method has been employed extensively for the analysis of ribonucleic acids, and gives reproducible results,166 but it has not been used to any great extent for deoxyribonucleic acids, probably because, under these conditions of hydrolysis, they yield some pyrimidine deoxy-ribonucleoside diphosphates.166... 

A nucleoside consists of a purine or pyrimidine base linked to a pentose, either D-ribose to form a ribonucleo-side or 2-deoxy-D-ribose to form a deoxyribonucleoside. Three major purine bases and their corresponding ribo-nucleosides are adenine/adenosine, guanine/guanosine and hypoxanthine/inosine. The three major pyrimidines and their corresponding ribonucleosides are cytosine/ cytodine, uracil/uradine and thymine/thymidine. A nucleotide such as ATP (Fig. 17-1) is a phosphate or polyphosphate ester of a nucleoside. 

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