The reactions of mercurated pyrimidine nucleotides with thiols and with hydrogen sulfide

Organomercury Nucleic Acids: Past, Present and Future

Synthetic efforts towards nucleosides, nucleotides, oligonucleotides and nucleic acids covalently mercurated at one or more of their base moieties are summarized, followed by a discussion of the proposed, realized and abandoned applications of this unique class of compounds. Special emphasis is given to fields in which active research is ongoing, notably the use of HgII -mediated base pairing to improve the hybridization properties of oligonucleotide probes. Finally, this minireview attempts to anticipate potential future applications of organomercury nucleic acids.

Mercurated nucleic acid probes, a new principle for non-radioactive in situ hybridization

This report describes the localization of specific nucleic acid sequences in interphase nuclei and metaphase chromosomes by a new hybridocytochemical method based on the use of mercurated nucleic acid probes. After the hybridization a sulfhydryl-hapten compound is reacted with the hybrids formed. A number of such ligands were synthesized and tested. A fluorescyl ligand could be used for the direct visualization of highly repetitive sequences. For indirect immunocytochemical visualization trinitrophenyl ligands were found to be more sensitive than biotinyl analogues. These ligands were applied for the detection of target sequences in metaphase chromosomes and interphase nuclei of somatic cell hybrids, human lymphoid cell lines and blood cell cultures. The sequences were in the range of high to low copy numbers. The lower limit of sensitivity is indicated by the visualization of two human unique DNA fragments (40 and 15.6 kb) in human metaphases. The method is rapid, gives consistent results and can be used for both RNA and DNA probes. Other potentials of the new principle are discussed.

A new hybridocytochemical method based on mercurated nucleic acid probes and sulfhydryl-hapten ligands. I. Stability of the mercury-sulfhydryl bond and influence of the ligand structure on immunochemical detection of the hapten

The mechanisms underlying a new hybridocytochemical method, which is based on mercurated nucleic acid probes and their binding to sulfhydryl-hapten ligands, have been studied. Furthermore we developed a simple procedure for the preparation of mercurated probes at a microgram scale. Nucleic acids immobilized on Sephadex beads have been immunochemically detected after hybridization with mercurated probes and binding of the sulfhydryl-hapten ligand trinitrophenyl-glutathione. In this system, the method proved to be specific and sensitive. However, the same procedure, when applied in situ, failed to give a positive result. ELISA experiments showed that these results cannot be attributed to a suboptimal immunochemical detection of the ligand. Chromatographic analysis of mercurated polynucleotide-ligand complexes revealed, however, an unexpected lability of the mercury-sulfhydryl bond. Under non-equilibrium conditions, as present during a cytochemical washing procedure, the mercury-sulfhydryl b ond was found to dissociate rapidly. On basis of these results the hypothesis was forwarded that the bond between mercurated nucleic acids immobilized on Sephadex and the ligand was stabilized by the positive charge of the Sephadex matrix. This charge was introduced during the cyanogen bromide activation and inactivation necessary for the covalent coupling of nucleic acids to Sephadex. In situ, however, no such positive charges are present. By reversing the charge of the ligand we expected to stabilize the mercury-sulfhydryl bond. In a subsequent paper data are presented that confirm this hypothesis.

Enzymatic polymerization of 5-mercuriuridine-5'-diphosphate with polynucleotide phosphorylase from E. coli

We report the polymerization of 5-mercuriuridine-5'-diphosphate (ppUHgX), in the presence of an excess of beta-mercaptoethanol, with polynucleotide phosphorylase from E. coli. A degradation of mercurated nucleotides with mercaptans was observed and about 30% of incorporation of mercury in the polymer was obtained after treatment with pancreatic RNase. The influence of ppUHgX and pUHgX with or without beta-mercaptoethanol was also studied on the polymerization of UDP. The ppUHgX did not polymerize in the absence of beta-mercaptoethanol.

Preparation and properties of monomercurated tRNA

Monomercurated tRNA has been prepared by exhaustive treatment of mercaptoethanol on polymercurated tRNA under non-denaturing conditions. The remained mercury atom is stable toward ultraviolet (254 nm) irradiation up to absorption of 100 quanta/nucleotide, but could be easily removed by mercaptoethanol under denaturing conditions. Monomercurated tRNA quantitatively binds to thiopropyl-Sepharose and can be completely desorbed by mercaptoethanol-containing solutions. Monomercurated tRNA is similar to the starting tRNA preparation in efficiency and specificity of aminoacylation and in factor-dependent polypeptide synthesis in vitro.

Properties of P3 esters of nucleoside triphosphates as substrates for RNA polymerase from Escherichia coli

P3-[(2,4-Dinitrophenyl)amino]ethyl (DNPNHEt) and P3-methyl phosphate esters of nucleoside 5'-triphosphates have been synthesized. Their properties as substrates in the initiation and elongation steps of transcription have been examined by using RNA polymerase from Escherichia coli and poly[d(A-T)] or T7 DNA as templates. It is shown that transcription can be initiated by ATP-EtNHDNP and that 2,4-dinitrophenyl residues are incorporated at the 5' end of the RNA molecules. Steady-state kinetic experiments of abortive initation on promoters A1 and A3 of T7 DNA revealed that ATP-EtNHDNP, ADP-EtNHDNP, and ATP-OCH3 have lower Km values and markedly reduced Vmax values compared to those of ATP. The two classes of esters, NTR-EtNHDNP and NTP-OCH3, were found to differ regarding their utilization as substrates for elongation. Both ATP-OCH3 and UTP-OCH3 are substrates for transcription. However, only the pyrimidine derivatives of NTP-EtNHDNP are elongation substrates which release DNPNHEt-PP upon utilization. This dramatic difference between the purine and pyrimidine derivatives of NTP-EtNHDNP reflects a selective process in the transcriptional complex for purines and pyrimidines.

Specificity of chromatin transcription in vitro. Asymmetric transcription of the globin gene by Escherichia coli RNA polymerase

The transcription of globin genes in mouse foetal liver chromatin and nuclei by exogenous Escherichia coli RNA polymerase is prone to artifacts due to RNA-dependent transcription of endogenous mRNA sequences. This is particularly evident when Mn2+ is used as divalent cation in the RNA transcription reaction. However, substitution or supplementation with Mg2+ eliminates this artifact and gives essentially asymmetric DNA-dependent transcription by the polymerase. In this paper we discuss a number of general criteria which can be applied to test the validity of specific gene transcription in vitro.

RNA synthesis in rabbit endometrial nuclei. Hormonal regulation of transcription of the uteroglobin gene

Endometrical nuclei, prepared from rabbits subjected to different hormonal treatments, were used for the cell-free synthesis of RNA. Optimal conditions for the incorporation of [3H]UMP into RNA are described, leading to the synthesis of relatively undegraded RNA molecules. Under these conditions there is virtually no initiation of new RNA chains in vitro, and RNA chain elongation is inhibited up to 60% by low concentrations of alpha-amanitin and up to 90% by actinomycin D. The synthesis of RNA is slightly inhibited in the presence of Hg-CTP and monothioglycerol, but newly synthesized mercurated RNA can be efficiently separated from endogenous RNA upon chromatography on sulfhydryl-Sepharose under stringent conditions. The RNA synthesized in vitro by endometrial nuclei from pseudopregnant rabbits contains RNA sequences transcribed from the uteroglobin gene, as demonstrated by hybridization to an excess of purified preuteroglobin cDNA. In endometrial cells from pseudopregnant animals the number of RNA polymerase II molecules transcribing the uteroglobin gene is 12-fold higher than in control animals, demonstrating that at least part of the hormonally induced accumulation of preuteroglobin mRNA is due to an increased rate of transcription of the uteroglobin gene.

RNA synthesis in isolated nuclei: the use of mercurated nucleotides

We have used uridine 5' triphosphate-5-mercury (Hg-UTP) in place of UTP to study RNA synthesis in a previously described isolated nuclei system (1). Employing isopycnic density gradient centrifugation to separate RNAs based upon their relative content of Hg-U, several conclusions can be drawn. In vitro RNA synthesis consists of end addition onto pre-initiated HnRNA molecules as well as apparent initiation of new HnRNA molecules de novo. Synthesis in our system continues linearly for greater than two hours. The chain elongation rate has been measured to be about 500 nucleotides per minute. The methods used to make these measurements are generally applicable to other in vitro systems.