Disulfide-linked oligonucleotide phosphorothioates: novel analogues of nucleic acids

DNA Phosphorothioate Modification Plays a Role in Peroxides Resistance in Streptomyces lividans

DNA phosphorothioation, conferred by dnd genes, was originally discovered in the soil-dwelling bacterium Streptomyces lividans, and thereafter found to exist in various bacterial genera. However, the physiological significance of this sulfur modification of the DNA backbone remains unknown in S. lividans. Our studies indicate that DNA phosphorothioation has a major role in resistance to oxidative stress in the strain. Although Streptomyces species express multiple catalase/peroxidase and organic hydroperoxide resistance genes to protect them against peroxide damage, a wild type strain of S. lividans exhibited two-fold to 10-fold higher survival, compared to a dnd⁻ mutant, following treatment with peroxides. RNA-seq experiments revealed that, catalase and organic hydroperoxide resistance gene expression were not up-regulated in the wild type strain, suggesting that the resistance to oxidative stress was not due to the up-regulation of these genes by DNA phosphorothioation. Quantitative RT-PCR analysis was conducted to trace the expression of the catalase and the organic hydroperoxide resistance genes after peroxides treatments. A bunch of these genes were activated in the dnd⁻ mutant rather than the wild type strain in response to peroxides. Moreover, the organic hydroperoxide peracetic acid was scavenged more rapidly in the presence than in the absence of phosphorothioate modification, both in vivo and in vitro. The dnd gene cluster can be up-regulated by the disulfide stressor diamide. Overall, our observations suggest that DNA phosphorothioate modification functions as a peroxide resistance system in S. lividans.

Biology by design: from top to bottom and back

Synthetic biology is a nascent technical discipline that seeks to enable the design and construction of novel biological systems to meet pressing societal needs. However, engineering biology still requires much trial and error because we lack effective approaches for connecting basic "parts" into higher-order networks that behave as predicted. Developing strategies for improving the performance and sophistication of our designs is informed by two overarching perspectives: "bottom-up" and "top-down" considerations. Using this framework, we describe a conceptual model for developing novel biological systems that function and interact with existing biological components in a predictable fashion. We discuss this model in the context of three topical areas: biochemical transformations, cellular devices and therapeutics, and approaches that expand the chemistry of life. Ten years after the construction of synthetic biology's first devices, the drive to look beyond what does exist to what can exist is ushering in an era of biology by design.

Maleimide-mediated protein conjugates of a nucleoside triphosphate gamma-S and an internucleotide phosphorothioate diester

The purpose of this study was to determine whether the gamma-S of nucleoside thiotriphosphates and the non-bridging sulfur of internucleotide phosphorothioate diesters possess sufficient thiol character to form adducts with maleimides. Adenosine triphosphate gamma-S (ATPS) and thymidyl-PS-thymidine (TPST) were each reacted with the reporter molecule N-1 pyrene maleimide (PM) and the fluorescence intensity was recorded. The observed reactivity of the phosphorothioate nucleotides towards maleimide was used as a basis for preparing covalent protein-nucleotide conjugates of ATPS and of the internucleotide phosphorothioate diester, deoxyadenylyl-PS-deoxy-adenylyl-PS-deoxyadenosine (dA3(PS)2). The absorbance spectra of bovine serum albumin (BSA) conjugates of ATPS and of dA3(PS)2 showed the formation of protein-nucleotide conjugates, with absorbance maxima near 260 nm. The degree of conjugation was 1.69 nucleotides (nt)/BSA molecule for ATPS and 0.44 nt/BSA molecule for dA3(PS)2. The extent of conjugation of the gamma-S of the nucleoside thiotriphosphate and of the non-bridging sulfur of the internucleotide phosphorothioate diester with maleimide-derivatized protein agreed with their relative reactivity towards PM. Both the gamma-S of the nucleoside thiotriphosphate and the internucleotide phosphorothioate diester were found to possess sufficient thiol character to permit formation of maleimide-mediated protein conjugates.

Substrate analogs as mechanistic probes for the bifunctional chorismate synthase from Neurospora crassa

Analogs of EPSP (4-8) have been prepared, and their activity as substrates for the chorismate synthase from Neurospora crassa has been characterized kinetically. The enzyme appears to show strict discrimination against substitution at the Z-position of the enol ether side chain as well as against substitution at the S-position of the reduced analogs. Both the glycolyl and (R)-lactyl analogs 4 and (R)-5 are good substrates, with (R)-5 having a higher V value than the natural substrate. Three substrates, including EPSP, have been found to show significant substrate inhibition with this enzyme, which at present can be explained by a noncompetitive model involving formation of a catalytically incompetent, ternary ES2 complex. A significant secondary kinetic isotope effect on V of 1.10 +/- 0.02 has been observed at C-3 with EPSP, indicating that C-O bond cleavage is kinetically significant at saturating substrate concentration; this effect is severely depressed at limiting substrate, with D(V/K) = 0.97 +/- 0.02. A similar effect is found for the primary deuterium isotope effect at C-6R, as observed previously [Balasubramanian, S., Davies, G. M., Coggins, J. R., & Abell, C. (1991) J. Am. Chem. Soc. 113, 8945-8946]. The primary isotope effects at C-6R with reduced analogs (R)-5 and (S)-6 are significantly larger than those with EPSP. The larger values of V and DV for (R)-5, when compared to EPSP, are evidence that release of chorismate is partially rate-limiting under saturating conditions. Incubation of the enzyme with reduced 5-deazaFMN does not result in any observable formation of chorismate, consistent with previous results indicating that reduced flavin is chemically involved in the synthesis of chorismate from EPSP [Ramjee, M. N., Balasubramanian, S., Abell, C., Coggins, J. R., Davies, G. M., Hawkes, T. R., Lowe, D. J., & Thorneley, R. N. F. (1992) J. Am. Chem. Soc. 114, 3151-3153].

Template controlled coupling and recombination of oligonucleotide blocks containing thiophosphoryl groups

Oxidation of a pair of 3'- and 5'-thiophosphoryloligonucleotides in the presence of a complementary oligonucleotide template is shown to provide an effective means for selectively linking oligonucleotide blocks. Coupling proceeds rapidly and efficiently under mild conditions in dilute aqueous solutions (microM range for oligomers, 2-15 min at 0-4 degrees C with K3Fe(CN)6 or KI3 as oxidant). This chemistry was demonstrated by polymerization of a thymidylate decamer derivative (sTTTTTTTTTTs) in the presence of poly(dA) and by coupling oligomers possessing terminal thiophosphoryl groups (ACACCCAATTs + sCTGAAAATGG and ACACCCAATs + sCTGAAAATGG) in the presence of a template (CCATTTTCAGAATTGGGTGT). Efficient linking of 5' to 3' phosphoryl groups can be achieved under conditions where virtually no coupling takes place in absence of a template. A novel feature of the chemistry is that catalyzed recombinations of oligomers containing internal -OP(O)(O-)SSP(O)(O-)O- linkages can be directed by hydrogen bonding to a complementary oligonucleotide. Convenient procedures are reported for solid phase synthesis of the requisite oligonucleotide 3'- and 5'-phosphorothioates.