Synthesis and properties of diastereoisomers of adenosine 5'-(O-1-thiotriphosphate) and adenosine 5'-(O-2-thiotriphosphate).

The chemical synthesis of adenosine 5'-(O-1-thiotriphosphate) (ATPalphaS) and adenosine 5'-(O-2-thiotriphosphate) (ATPbetaS) is described. Both exist as a pair of diastereomers, A and B. The isomers of ATPalphaS can be distinguished on the basis of their different reaction rates with myokinase as well as nucleoside diphosphate kinase. With both enzymes, isomer A reacts fast whereas isomer B reacts considerably more slowly. Phosphorylation of a mixture of isomers of ADPalphaS with pyruvate or acetate kinase yields ATPalphaS, isomer A, whereas the phosphoryl transfer with creatine or arginine kinase yields isomer B. The isomers of ATPbetaS differ in their reactivity with myosin. Isomer A is readily hydrolyzed, whereas isomer B is not. However, isomer B reacts faster with nucleoside diphosphate kinase and ADP than isomer A. Phosphoryl transfer with pyruvate kinase onto ADPbetaS yields ATPbetaS, isomer A, with acetate kinase, isomer B.     

Purine and pyrimidine nucleotides potentiate activation of NADPH oxidase and degranulation by chemotactic peptides and induce aggregation of human neutrophils via G proteins

Whereas the chemotactic peptide, N-formyl-L-methionyl-L-leucyl-L-phenylalanine (fMet-Leu-Phe), induced NADPH-oxidase-catalyzed superoxide (O2-) formation in human neutrophils, purine and pyrimidine nucleotides per se did not stimulate NADPH oxidase but enhanced O2- formation induced by submaximally and maximally stimulatory concentrations of fMet-Leu-Phe up to fivefold. On the other hand, FMet-Leu-Phe primed neutrophils to generate O2- upon exposure to nucleotides. At a concentration of 100 microM, purine nucleotides enhanced O2- formation in the effectiveness order adenosine 5'-O-[3-thio]triphosphate (ATP[gamma S]) greater than ITP greater than guanosine 5'-O-[3-thio]triphosphate (GTP[gamma S]) greater than ATP = adenosine 5'-O-[2-thio]triphosphate (Sp-diastereomer) = GTP = guanosine 5'-O-[2-thio]diphosphate (GDP[beta S] = ADP greater than adenosine 5'-[beta, gamma-imido]triphosphate = adenosine 5'-O-[2-thio]triphosphate] (Rp-diastereomer). Pyrimidine nucleotides stimulated fMet-Leu-Phe-induced O2- formation in the effectiveness order uridine 5'-O-[3-thio]triphosphate (UTP[gamma S]) = UTP greater than CTP. Uracil (UDP[beta S]) = uridine 5'-O[2-thio]triphosphate (Rp-diastereomer) (Rp)-UTP[beta S]) = UTP greater than CTP. Uracil nucleotides were similarly effective potentiators of O2- formation as the corresponding adenine nucleotides. GDP[beta S] and UDP[beta S] synergistically enhanced the stimulatory effects of ATP[gamma S], GTP[gamma S] and UTP[gamma S]. Purine and pyrimidine nucleotides did not induce degranulation in neutrophils but potentiated fMet-Leu-Phe-induced release of beta-glucuronidase with similar nucleotide specificities as for O2- formation. In contrast, nucleotides per se induced aggregation of neutrophils. Treatment with pertussis toxin prevented aggregation induced by both nucleotides and fMet-Leu-Phe. Our results suggest that purine and pyrimidine nucleotides act via nucleotide receptors, the nucleotide specificity of which is different from nucleotide receptors in other cell types. Neutrophil nucleotide receptors are coupled to guanine-nucleotide-binding proteins. As nucleotides are released from cells under physiological and pathological conditions, they may play roles as intercellular signal molecules in neutrophil activation.     

Strand specific cleavage of phosphorothioate-containing DNA by reaction with restriction endonucleases in the presence of ethidium bromide.

A method for achieving strand specific nicking of DNA has been developed. Phosphorothioate groups were incorporated enzymatically into the (-)strand of M13 RF IV DNA. When such DNA is reacted with restriction endonucleases in the presence of ethidium bromide nicked DNA (RF II) is produced. All of the restriction enzymes tested linearised phosphorothioate-containing DNA in the absence of this dye. The strand specificity of the reaction was investigated by employing the ethidium bromide mediated nicking reaction in the phosphorothioate-based oligonucleotide-directed mutagenesis method. The mutational efficiencies obtained were in the region of 64-89%, indicating that these restriction enzymes hydrolyse the phosphodiester bond at the cleavage site of the unsubstituted (+)strand.     

Rapid high-efficiency site-directed mutagenesis by the phosphorothioate approach.

Several improvements to the existing phosphorothioate-based site-directed mutagenesis methodology are reported, and here it is demonstrated that the new procedure is able to produce large deletions, insertions and point mutations rapidly and with very high efficiency. The time required for the polymerization step has been reduced by using T7 DNA polymerase to extend the mutant oligonucleotide primer-template. The reaction produces good yields of double-stranded closed-circular DNA and some partially polymerized template. The reaction was treated with T5 D15 exonuclease to selectively destroy partially polymerized single-stranded phage DNA that may otherwise contribute to an increased background of wild-type transformants. The use of these enzymes greatly facilitates the implementation of the phosphorothioate-based site-directed mutagenesis method by requiring less template DNA and by allowing all the in vitro manipulations to be completed in a day. In its present form the method may easily be automated, enabling large systematic site-directed mutagenesis projects to be undertaken.     

Synthesis of d(GC) and d(CG) octamers containing alternating phosphorothioate linkages: effect of the phosphorothioate group on the B-Z transition

The synthesis of four oligonucleotides containing alternating phosphorothioate groups, (Rp)-and (Sp)-d[G(p(S)CpG)3p(S)C] and (Rp)- and (Sp)-d[C(p(S)GpC)p(S)G], by the phosphite approach is described. Silica gel to which 2'(3')-O-acetyluridine and 5'-succinyl groups were bound served as support for oligomer synthesis. The syntheses were carried out by dimer addition with presynthesized diastereomerically pure dinucleoside phosphorothioates as building blocks. The products were characterized by 31P NMR, nuclease P1 digestion, and oxidation to the corresponding all-phosphate-containing oligomers. The ability of each oligomer to adopt the Z conformation under high-salt conditions was screened for by circular dichroism spectroscopy. Both (Rp)-d[G(p(S)CpG)3p(S)C] and (Sp)-d[C(p(S)GpC)3p(S)G] are capable of forming Z-type structures at high NaCl concentrations. In the case of (Rp)-d[G(p(S)CpG)3p(S)C] where a phosphorothioate of the Rp configuration occurs 5' to a deoxycytidine residue, the B----Z transition is potentiated in comparison to the unmodified oligomer. (Sp)-d[G(p(S)CpG)3p(S)C] and (Rp)-d[C(p(S)GpC)3p(S)G] retain the B conformation even at high NaCl concentration.     

The use of phosphorothioate-modified DNA in restriction enzyme reactions to prepare nicked DNA

The RF IV form of M13 DNA was synthesized enzymatically in vitro, using the viral (+)strand as template, to contain phosphorothioate-modified internucleotidic linkages of the Rp configuration on the 5' side of every base of a particular type in the newly-synthesized (-)strand. Twenty nine restriction enzymes were then tested for their reactions with the appropriate modified DNA types having a phosphorothioate linkage placed exactly at the cleavage site(s) of these enzymes in the (-)strand. Eleven of the seventeen restriction enzymes tested that had recognition sequences of five bases or more could be used to convert the phosphorothioate DNA entirely into the nicked form, either by simply allowing the reaction to go to completion with excess enzyme (Ava I, Ava II, Ban II, Hind II, Nci I, Pst I or Pvu I) or by stopping the reaction at the appropriate time before the nicked DNA is linearized (Bam HI, Bgl I, Eco RI or Hind III). Only modification of the exact cleavage site in the (-)strand could block linearization by the first class of enzymes. The results presented imply that the restriction enzyme-directed nicking of phosphorothioate M13 DNA occurs exclusively in the (+)strand.     

Inhibition of restriction endonuclease Nci I cleavage by phosphorothioate groups and its application to oligonucleotide-directed mutagenesis.

M13 RF IV DNA where phosphorothioate groups are incorporated at restriction endonuclease Nci I recognition sites in the (-)strand is efficiently nicked by the action of this enzyme. Incubation of such nicked DNA with exonuclease III produces gapped DNA. The gap can be filled by reaction with deoxynucleoside triphosphates and DNA polymerase I. When this sequence of reactions is performed with DNA containing a mismatch oligonucleotide primer in the (-)-strand mutational frequencies of 70-90% can be obtained upon transformation. The general nature of this methodology has been further shown to be applicable to other restriction enzymes such as Hind II, Pst I and Fsp I. The mutational frequency obtained using these enzymes is between 40-80% mainly because of less efficient nicking and gapping. Studies on inhibition of Nci I cleavage show that in addition to a phosphorothioate group at the position of cleavage an additional group in the 5'-neighbouring position is necessary for complete inhibition.